JP4831663B2 - Thin plate-like porous silica metal composite particles and production method thereof - Google Patents
Thin plate-like porous silica metal composite particles and production method thereof Download PDFInfo
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- JP4831663B2 JP4831663B2 JP2005313537A JP2005313537A JP4831663B2 JP 4831663 B2 JP4831663 B2 JP 4831663B2 JP 2005313537 A JP2005313537 A JP 2005313537A JP 2005313537 A JP2005313537 A JP 2005313537A JP 4831663 B2 JP4831663 B2 JP 4831663B2
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- VYPSYNLAJGMNEJ-UHFFFAOYSA-N Silicium dioxide Chemical compound O=[Si]=O VYPSYNLAJGMNEJ-UHFFFAOYSA-N 0.000 title claims description 319
- 239000002245 particle Substances 0.000 title claims description 155
- 239000000377 silicon dioxide Substances 0.000 title claims description 142
- 239000002905 metal composite material Substances 0.000 title claims description 115
- 238000004519 manufacturing process Methods 0.000 title claims description 25
- 239000011148 porous material Substances 0.000 claims description 96
- 229910052751 metal Inorganic materials 0.000 claims description 79
- 239000002184 metal Substances 0.000 claims description 74
- 238000006243 chemical reaction Methods 0.000 claims description 56
- 238000003756 stirring Methods 0.000 claims description 40
- 239000002736 nonionic surfactant Substances 0.000 claims description 39
- 150000003839 salts Chemical class 0.000 claims description 26
- 229910052910 alkali metal silicate Inorganic materials 0.000 claims description 22
- 238000000034 method Methods 0.000 claims description 22
- 230000032683 aging Effects 0.000 claims description 19
- XLYOFNOQVPJJNP-UHFFFAOYSA-N water Substances O XLYOFNOQVPJJNP-UHFFFAOYSA-N 0.000 claims description 19
- QGZKDVFQNNGYKY-UHFFFAOYSA-N Ammonia Chemical compound N QGZKDVFQNNGYKY-UHFFFAOYSA-N 0.000 claims description 18
- 238000002156 mixing Methods 0.000 claims description 18
- 229910004298 SiO 2 Inorganic materials 0.000 claims description 17
- 239000003054 catalyst Substances 0.000 claims description 16
- 229910052719 titanium Inorganic materials 0.000 claims description 14
- 238000003795 desorption Methods 0.000 claims description 13
- 238000009826 distribution Methods 0.000 claims description 13
- 239000002253 acid Substances 0.000 claims description 12
- 239000007864 aqueous solution Substances 0.000 claims description 12
- 239000011259 mixed solution Substances 0.000 claims description 11
- 229910052726 zirconium Inorganic materials 0.000 claims description 11
- BPQQTUXANYXVAA-UHFFFAOYSA-N Orthosilicate Chemical group [O-][Si]([O-])([O-])[O-] BPQQTUXANYXVAA-UHFFFAOYSA-N 0.000 claims description 10
- 239000000463 material Substances 0.000 claims description 10
- 239000007787 solid Substances 0.000 claims description 10
- 238000001228 spectrum Methods 0.000 claims description 10
- 230000002378 acidificating effect Effects 0.000 claims description 9
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- 239000000243 solution Substances 0.000 description 30
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- VEXZGXHMUGYJMC-UHFFFAOYSA-N Hydrochloric acid Chemical compound Cl VEXZGXHMUGYJMC-UHFFFAOYSA-N 0.000 description 29
- 239000002994 raw material Substances 0.000 description 24
- 239000011734 sodium Substances 0.000 description 16
- 229920002415 Pluronic P-123 Polymers 0.000 description 15
- 239000004115 Sodium Silicate Substances 0.000 description 14
- 230000015572 biosynthetic process Effects 0.000 description 14
- NTHWMYGWWRZVTN-UHFFFAOYSA-N sodium silicate Chemical compound [Na+].[Na+].[O-][Si]([O-])=O NTHWMYGWWRZVTN-UHFFFAOYSA-N 0.000 description 14
- 229910052911 sodium silicate Inorganic materials 0.000 description 14
- 229920003171 Poly (ethylene oxide) Polymers 0.000 description 13
- 229920000428 triblock copolymer Polymers 0.000 description 13
- 238000001878 scanning electron micrograph Methods 0.000 description 12
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- 239000002243 precursor Substances 0.000 description 7
- 229910052708 sodium Inorganic materials 0.000 description 7
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- IJGRMHOSHXDMSA-UHFFFAOYSA-N Atomic nitrogen Chemical compound N#N IJGRMHOSHXDMSA-UHFFFAOYSA-N 0.000 description 6
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- AFCARXCZXQIEQB-UHFFFAOYSA-N N-[3-oxo-3-(2,4,6,7-tetrahydrotriazolo[4,5-c]pyridin-5-yl)propyl]-2-[[3-(trifluoromethoxy)phenyl]methylamino]pyrimidine-5-carboxamide Chemical compound O=C(CCNC(=O)C=1C=NC(=NC=1)NCC1=CC(=CC=C1)OC(F)(F)F)N1CC2=C(CC1)NN=N2 AFCARXCZXQIEQB-UHFFFAOYSA-N 0.000 description 4
- 229910021536 Zeolite Inorganic materials 0.000 description 4
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- 239000000654 additive Substances 0.000 description 4
- HNPSIPDUKPIQMN-UHFFFAOYSA-N dioxosilane;oxo(oxoalumanyloxy)alumane Chemical compound O=[Si]=O.O=[Al]O[Al]=O HNPSIPDUKPIQMN-UHFFFAOYSA-N 0.000 description 4
- 150000002605 large molecules Chemical class 0.000 description 4
- 229920002521 macromolecule Polymers 0.000 description 4
- 239000000203 mixture Substances 0.000 description 4
- 150000002894 organic compounds Chemical class 0.000 description 4
- -1 polyoxyethylene Polymers 0.000 description 4
- 238000000746 purification Methods 0.000 description 4
- 238000011160 research Methods 0.000 description 4
- 241000894007 species Species 0.000 description 4
- 239000010457 zeolite Substances 0.000 description 4
- VZSRBBMJRBPUNF-UHFFFAOYSA-N 2-(2,3-dihydro-1H-inden-2-ylamino)-N-[3-oxo-3-(2,4,6,7-tetrahydrotriazolo[4,5-c]pyridin-5-yl)propyl]pyrimidine-5-carboxamide Chemical compound C1C(CC2=CC=CC=C12)NC1=NC=C(C=N1)C(=O)NCCC(N1CC2=C(CC1)NN=N2)=O VZSRBBMJRBPUNF-UHFFFAOYSA-N 0.000 description 3
- QTBSBXVTEAMEQO-UHFFFAOYSA-N Acetic acid Chemical compound CC(O)=O QTBSBXVTEAMEQO-UHFFFAOYSA-N 0.000 description 3
- 102000004190 Enzymes Human genes 0.000 description 3
- 108090000790 Enzymes Proteins 0.000 description 3
- HEMHJVSKTPXQMS-UHFFFAOYSA-M Sodium hydroxide Chemical compound [OH-].[Na+] HEMHJVSKTPXQMS-UHFFFAOYSA-M 0.000 description 3
- 229910007926 ZrCl Inorganic materials 0.000 description 3
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- 125000000524 functional group Chemical group 0.000 description 3
- 125000001165 hydrophobic group Chemical group 0.000 description 3
- 229910052757 nitrogen Inorganic materials 0.000 description 3
- 231100000252 nontoxic Toxicity 0.000 description 3
- 230000003000 nontoxic effect Effects 0.000 description 3
- CMOAHYOGLLEOGO-UHFFFAOYSA-N oxozirconium;dihydrochloride Chemical compound Cl.Cl.[Zr]=O CMOAHYOGLLEOGO-UHFFFAOYSA-N 0.000 description 3
- 229920000642 polymer Polymers 0.000 description 3
- 238000000634 powder X-ray diffraction Methods 0.000 description 3
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- 239000000741 silica gel Substances 0.000 description 3
- 229910002027 silica gel Inorganic materials 0.000 description 3
- 239000000725 suspension Substances 0.000 description 3
- XJDNKRIXUMDJCW-UHFFFAOYSA-J titanium tetrachloride Chemical compound Cl[Ti](Cl)(Cl)Cl XJDNKRIXUMDJCW-UHFFFAOYSA-J 0.000 description 3
- AUHZEENZYGFFBQ-UHFFFAOYSA-N 1,3,5-trimethylbenzene Chemical compound CC1=CC(C)=CC(C)=C1 AUHZEENZYGFFBQ-UHFFFAOYSA-N 0.000 description 2
- LDXJRKWFNNFDSA-UHFFFAOYSA-N 2-(2,4,6,7-tetrahydrotriazolo[4,5-c]pyridin-5-yl)-1-[4-[2-[[3-(trifluoromethoxy)phenyl]methylamino]pyrimidin-5-yl]piperazin-1-yl]ethanone Chemical compound C1CN(CC2=NNN=C21)CC(=O)N3CCN(CC3)C4=CN=C(N=C4)NCC5=CC(=CC=C5)OC(F)(F)F LDXJRKWFNNFDSA-UHFFFAOYSA-N 0.000 description 2
- WTFUTSCZYYCBAY-SXBRIOAWSA-N 6-[(E)-C-[[4-[2-(2,3-dihydro-1H-inden-2-ylamino)pyrimidin-5-yl]piperazin-1-yl]methyl]-N-hydroxycarbonimidoyl]-3H-1,3-benzoxazol-2-one Chemical compound C1C(CC2=CC=CC=C12)NC1=NC=C(C=N1)N1CCN(CC1)C/C(=N/O)/C1=CC2=C(NC(O2)=O)C=C1 WTFUTSCZYYCBAY-SXBRIOAWSA-N 0.000 description 2
- LFQSCWFLJHTTHZ-UHFFFAOYSA-N Ethanol Chemical compound CCO LFQSCWFLJHTTHZ-UHFFFAOYSA-N 0.000 description 2
- KRHYYFGTRYWZRS-UHFFFAOYSA-M Fluoride anion Chemical compound [F-] KRHYYFGTRYWZRS-UHFFFAOYSA-M 0.000 description 2
- QAOWNCQODCNURD-UHFFFAOYSA-N Sulfuric acid Chemical compound OS(O)(=O)=O QAOWNCQODCNURD-UHFFFAOYSA-N 0.000 description 2
- 238000004458 analytical method Methods 0.000 description 2
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- 229910021645 metal ion Inorganic materials 0.000 description 2
- 239000002105 nanoparticle Substances 0.000 description 2
- UJVRJBAUJYZFIX-UHFFFAOYSA-N nitric acid;oxozirconium Chemical compound [Zr]=O.O[N+]([O-])=O.O[N+]([O-])=O UJVRJBAUJYZFIX-UHFFFAOYSA-N 0.000 description 2
- 230000000149 penetrating effect Effects 0.000 description 2
- 235000012239 silicon dioxide Nutrition 0.000 description 2
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- 238000002371 ultraviolet--visible spectrum Methods 0.000 description 2
- 229910052720 vanadium Inorganic materials 0.000 description 2
- LGXAANYJEHLUEM-UHFFFAOYSA-N 1,2,3-tri(propan-2-yl)benzene Chemical compound CC(C)C1=CC=CC(C(C)C)=C1C(C)C LGXAANYJEHLUEM-UHFFFAOYSA-N 0.000 description 1
- OHVLMTFVQDZYHP-UHFFFAOYSA-N 1-(2,4,6,7-tetrahydrotriazolo[4,5-c]pyridin-5-yl)-2-[4-[2-[[3-(trifluoromethoxy)phenyl]methylamino]pyrimidin-5-yl]piperazin-1-yl]ethanone Chemical compound N1N=NC=2CN(CCC=21)C(CN1CCN(CC1)C=1C=NC(=NC=1)NCC1=CC(=CC=C1)OC(F)(F)F)=O OHVLMTFVQDZYHP-UHFFFAOYSA-N 0.000 description 1
- HMUNWXXNJPVALC-UHFFFAOYSA-N 1-[4-[2-(2,3-dihydro-1H-inden-2-ylamino)pyrimidin-5-yl]piperazin-1-yl]-2-(2,4,6,7-tetrahydrotriazolo[4,5-c]pyridin-5-yl)ethanone Chemical compound C1C(CC2=CC=CC=C12)NC1=NC=C(C=N1)N1CCN(CC1)C(CN1CC2=C(CC1)NN=N2)=O HMUNWXXNJPVALC-UHFFFAOYSA-N 0.000 description 1
- WZFUQSJFWNHZHM-UHFFFAOYSA-N 2-[4-[2-(2,3-dihydro-1H-inden-2-ylamino)pyrimidin-5-yl]piperazin-1-yl]-1-(2,4,6,7-tetrahydrotriazolo[4,5-c]pyridin-5-yl)ethanone Chemical compound C1C(CC2=CC=CC=C12)NC1=NC=C(C=N1)N1CCN(CC1)CC(=O)N1CC2=C(CC1)NN=N2 WZFUQSJFWNHZHM-UHFFFAOYSA-N 0.000 description 1
- IHCCLXNEEPMSIO-UHFFFAOYSA-N 2-[4-[2-(2,3-dihydro-1H-inden-2-ylamino)pyrimidin-5-yl]piperidin-1-yl]-1-(2,4,6,7-tetrahydrotriazolo[4,5-c]pyridin-5-yl)ethanone Chemical compound C1C(CC2=CC=CC=C12)NC1=NC=C(C=N1)C1CCN(CC1)CC(=O)N1CC2=C(CC1)NN=N2 IHCCLXNEEPMSIO-UHFFFAOYSA-N 0.000 description 1
- NIPNSKYNPDTRPC-UHFFFAOYSA-N N-[2-oxo-2-(2,4,6,7-tetrahydrotriazolo[4,5-c]pyridin-5-yl)ethyl]-2-[[3-(trifluoromethoxy)phenyl]methylamino]pyrimidine-5-carboxamide Chemical compound O=C(CNC(=O)C=1C=NC(=NC=1)NCC1=CC(=CC=C1)OC(F)(F)F)N1CC2=C(CC1)NN=N2 NIPNSKYNPDTRPC-UHFFFAOYSA-N 0.000 description 1
- GRYLNZFGIOXLOG-UHFFFAOYSA-N Nitric acid Chemical compound O[N+]([O-])=O GRYLNZFGIOXLOG-UHFFFAOYSA-N 0.000 description 1
- 239000004743 Polypropylene Substances 0.000 description 1
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- 150000004703 alkoxides Chemical class 0.000 description 1
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- 238000009616 inductively coupled plasma Methods 0.000 description 1
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- 239000002563 ionic surfactant Substances 0.000 description 1
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- 229910052748 manganese Inorganic materials 0.000 description 1
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- 150000002739 metals Chemical class 0.000 description 1
- 150000002823 nitrates Chemical class 0.000 description 1
- 229910017604 nitric acid Inorganic materials 0.000 description 1
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- 239000001301 oxygen Substances 0.000 description 1
- 229910052760 oxygen Inorganic materials 0.000 description 1
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Landscapes
- Solid-Sorbent Or Filter-Aiding Compositions (AREA)
- Silicon Compounds (AREA)
- Catalysts (AREA)
Description
本発明は、ハニカム状に規則配列した3nm(1000℃焼成物の細孔径が小さくなることによって数値を5から3に変更)以上の細孔径を有する薄板状多孔質シリカ金属複合体粒子とその製造方法に関するものである。より詳細には、本発明は、非イオン性界面活性剤の円盤状分子集合体形成能に基づいて、アルカリ珪酸塩から生成するシリカ溶存種と非イオン性界面活性剤との高次規則構造体形成能を利用して、ハニカム状に規則配列した幅3nm以上の1次元メソ細孔を持ち、0.5ミクロン未満の厚さの薄片状粒子形態を有する、ミクロ構造の規則性とマクロ形態を制御した薄板状多孔質シリカ金属複合体粒子とその製造法に関するものである。 The present invention relates to a thin plate-like porous silica metal composite particle having a pore diameter of 3 nm or more regularly arranged in a honeycomb shape (the numerical value is changed from 5 to 3 when the pore diameter of a 1000 ° C. fired product is reduced) and the production thereof. It is about the method. More specifically, the present invention relates to a high-order ordered structure of a silica-dissolved species generated from an alkali silicate and a nonionic surfactant based on the discotic molecular aggregate forming ability of the nonionic surfactant. Utilizing the forming ability, the regularity of the microstructure and the macro form have one-dimensional mesopores with a width of 3 nm or more arranged in a honeycomb shape and have a flaky particle form with a thickness of less than 0.5 microns. The present invention relates to a controlled thin plate-like porous silica metal composite particle and a production method thereof.
1992年界面活性剤のミセル規則集合体形成能に基づいて合成されるメソポーラス物質の発見以来、メソ細孔の規則構造のみならず、ミクロンからミリメートルサイズのマクロ形態まで制御した高次規則構造を有する多孔質材料の研究開発が活発に行われている(非特許文献1)。また、現在ではシリカ系のみならず金属酸化物に関するメソポーラス材料の開発も重要な研究課題となっている。合成法においても、環境への負荷の抑制並びに経済的なコスト面から、ポリマー系の非イオン系界面活性剤、またシリカ原料としてアルカリ珪酸塩を使用する方法が注目されている(非特許文献2)。 Since the discovery of mesoporous materials synthesized based on the ability of micelle ordered aggregates to form surfactants in 1992, it has not only the regular structure of mesopores but also a highly ordered structure controlled from micron to millimeter size macro form Research and development of porous materials are being actively carried out (Non-patent Document 1). At present, the development of mesoporous materials not only for silica but also for metal oxides is an important research subject. Also in the synthesis method, a method using a polymer-based nonionic surfactant or an alkali silicate as a silica raw material has attracted attention from the viewpoint of suppression of environmental burden and economical cost (Non-patent Document 2). ).
しかし、アルカリ珪酸塩とポリマー系の非イオン系界面活性剤を同時に使用し、且つマクロ形態を制御した報告例は極めて少ないのが現状である。その例として次の数例を挙げることができる。
(1)塩酸に溶解し、2℃に維持した直鎖非イオン性ポリオキシエチレン酸性溶液に、珪酸ナトリウム水溶液を添加し、安定なミセル集合体を調整した後、20〜70℃に加温し、更にシリカの縮重合を進行させる為にフッ化物を添加して3日間の反応を行うことで、直径5μm程度の球状シリカメソ多孔体を合成している(非特許文献3)。
(2)塩酸に溶解したトリブロック共重合体溶液に、エタノールを溶媒としたTMB(1,3,5-トリメチルベンゼン)溶液を混合し、強攪拌下で珪酸ナトリウム水溶液を滴下する。さらにNaOHでpH調整し、4時間熟成することで、中空状球形メソポーラスシリカを合成している(非特許文献4)。
However, there are very few reports on the use of alkali silicates and polymer-based nonionic surfactants at the same time and the macro form is controlled. The following several examples can be mentioned as the example.
(1) To a linear nonionic polyoxyethylene acidic solution dissolved in hydrochloric acid and maintained at 2 ° C., an aqueous sodium silicate solution is added to prepare a stable micelle assembly, and then heated to 20 to 70 ° C. Further, a spherical silica mesoporous material having a diameter of about 5 μm is synthesized by adding a fluoride to cause the condensation polymerization of silica to proceed and reacting for 3 days (Non-patent Document 3).
(2) A TMB (1,3,5-trimethylbenzene) solution using ethanol as a solvent is mixed with a triblock copolymer solution dissolved in hydrochloric acid, and an aqueous sodium silicate solution is added dropwise with vigorous stirring. Further, hollow spherical mesoporous silica is synthesized by adjusting the pH with NaOH and aging for 4 hours (Non-patent Document 4).
また、本発明者らによって、(3)アルカリ珪酸塩と非イオン系界面活性剤としてトリブロック共重合体を使用して球状シリカ多孔体が合成できることが報告されている(特許文献1)。さらに、(4)アルカリ珪酸塩と非イオン系界面活性剤としてトリブロック共重合体を使用してロッド状並びに繊維状メソシリカ多孔体が合成できることも明らかにされている(特許文献2)。この公知技術においては、珪酸ソーダとトリブロック共重合体(商品名
Pluronic P123)を塩酸酸性溶液中において反応させ、攪拌の有無によって、単分散ロッド状並びに繊維状のシリカメソ多孔体を選択的に合成している。
In addition, the present inventors have reported that (3) a spherical silica porous body can be synthesized using a triblock copolymer as an alkali silicate and a nonionic surfactant (Patent Document 1). Furthermore, (4) it has also been clarified that rod-like and fibrous mesosilica porous bodies can be synthesized using alkali silicate and a triblock copolymer as a nonionic surfactant (Patent Document 2). In this known technique, sodium silicate and triblock copolymer (trade name)
Pluronic P123) is reacted in an acidic hydrochloric acid solution, and monodispersed rod-like and fibrous silica mesoporous materials are selectively synthesized depending on the presence or absence of stirring.
しかし、上記公知技術においては、ロッド状粒子の長さ方向(厚さ)の制御方法に関しては全く検討されておらず、薄板状のメソポーラス粒子並びに製造方法は明らかにされていない。一方、シリカ骨格中の金属元素は酸化、還元触媒発現サイト、あるいは種々の触媒担体として有用である。非イオン系界面活性剤を用いる場合、強酸性下での合成が一般的で、直接反応によってシリカ骨格中のSiを他金属で置換することは難しいことが知られている(非特許文献5)。強酸下では金属元素イオン(M)は孤立して存在し、シリカ骨格中にそのまま取り込むことができれば極めて高分散状態で存在することが期待されるが、実際にはSi−O−Mの結合が形成され難い。そのため、金属元素を含むシリカ系多孔質材料を合成するには、多くはアルカリ性条件下での直接反応、あるいは一旦作製した多孔体の細孔表面を金属元素によって化学修飾するといった間接的な方法が適用される。 However, in the above-mentioned known technology, no study has been made regarding a method for controlling the length direction (thickness) of the rod-like particles, and the thin plate-like mesoporous particles and the production method have not been clarified. On the other hand, the metal element in the silica skeleton is useful as an oxidation, reduction catalyst expression site, or various catalyst carriers. When a nonionic surfactant is used, synthesis under strong acid is common, and it is known that it is difficult to substitute Si in the silica skeleton with another metal by direct reaction (Non-patent Document 5). . Under strong acid, the metal element ion (M) is present in isolation, and if it can be incorporated into the silica skeleton as it is, it is expected to exist in a very highly dispersed state, but in reality, the Si—OM bond is present. It is difficult to form. Therefore, in order to synthesize a silica-based porous material containing a metal element, indirect methods such as direct reaction under alkaline conditions or chemical modification of the pore surface of a porous body once produced with a metal element are often used. Applied.
さらに、薄膜状メソポーラス物質の研究は盛んであるが、特に膜平面の垂直方向に1次元メソチャンネルが貫通した合成例は難しく、その例はほとんど知られていない。さらに、シリカ骨格中のSiを他の金属元素で置換したメソポーラス物質は種々報告されているが、強酸性下では金属イオンは孤立して存在し金属イオンが酸素イオンを介してSiと結合し難いことからメタロシリケート(シリカ骨格中のSiを他金属元素で置換したシリカ化合物)の直接合成は稀であり、これまで、金属元素を含むシリカ系多孔質材料において一次元メソ孔がハニカム状に規則配列した薄板状の形態を有するメソポーラス材料は知られていない。 Furthermore, although research on thin-film mesoporous materials is active, a synthesis example in which a one-dimensional mesochannel penetrates in the direction perpendicular to the membrane plane is difficult, and few examples are known. Furthermore, various mesoporous materials in which Si in the silica skeleton is substituted with other metal elements have been reported. However, under strong acidity, metal ions exist in isolation, and metal ions are difficult to bind to Si through oxygen ions. Therefore, the direct synthesis of metallosilicates (silica compounds in which Si in the silica skeleton is substituted with other metal elements) is rare, and so far, one-dimensional mesopores are ordered in a honeycomb shape in silica-based porous materials containing metal elements. There is no known mesoporous material having an array of lamellar shapes.
また、均一細孔を有する物質において、細孔径を拡張することは、細孔を反応場とする化学反応において、従来不可能であった大きな分子を対象とすることを可能とするもので、学術的及び実用的に極めて重要な研究課題である。ゼオライト開発の経緯、並びにメソポア多孔体の発明とその後の強い関心と現在まで衰えぬ基礎研究並びに応用開発への期待がこのことを物語っている(非特許文献6)。一方、メソポーラス材料の合成手法においては、使用する界面活性剤の種類等、反応条件によって細孔径が制御でき、特に疎水基が長くなる程、大きな細孔径を持つものが得られる傾向が認められる。また、ミセルを大きくする添加助剤1,3,5−トリメルベンゼン、トリイソプロピルベンゼン等の有機化合物を使用することで細孔径の拡張が可能である。さらに、シリカメソ多孔体合成時におけるフッ化物添加効果として、シリカ骨格の形成を促進するばかりでなく(非特許文献7)、細孔径拡張効果が報告されている(非特許文献8)。さらに、非イオン系界面活性剤を用いる場合、3次元規則ミセル集合体の形成に障害のない範囲で反応温度を高くすることによってメソポア多孔体の細孔径を拡張できることが知られている。
上記の通り、珪酸ソーダとトリブロック共重合体を使用してマクロ形態を制御した多孔質粒子の報告例は極めて少なく、薄板状で、しかもシリカ骨格中のSiを他金属元素で置換した薄板状多孔質シリカ金属複合体粒子の合成例は報告されていない。まして、薄板状のマクロ形態を保持したまま、シリカ骨格中に多価金属を導入しかつ細孔径を拡張することはこれまでにない新規な方法によってしか達成できない。 As mentioned above, there are very few reports of porous particles whose macro morphology is controlled using sodium silicate and triblock copolymer, and it is a thin plate shape, and a thin plate shape in which Si in the silica skeleton is substituted with another metal element No synthesis example of porous silica metal composite particles has been reported. Furthermore, introducing a polyvalent metal into the silica skeleton and expanding the pore diameter while maintaining the thin plate-like macro form can be achieved only by a novel method that has not been achieved so far.
そこで、本発明者らは、安価なアルカリ珪酸塩をシリカ源とし、無毒性の非イオン性界面活性剤をテンプレートとするとの本発明者によりこれまでに開発された技術を踏まえ、酸化、還元触媒発現サイトとしての金属元素をシリカ骨格中に有し、触媒として、あるいは触媒担体として、化学工業、環境浄化、食品工業、医療、あるいはセンサー等としての有用性が大きく期待される。薄板状形態を保持したまま、シリカ骨格中のSiを他金属で置換した、薄板状多孔質シリカ金属複合体粒子とその製造方法、および前記の特徴を有する薄板状多孔質シリカ金属複合体粒子において細孔径の拡張法等の新しい技術手段と、その結果得られる大細孔径薄板状多孔質シリカ金属複合体粒子を提供することを課題としている。さらに、本薄板状多孔質シリカ金属複合体粒子は、1000℃以上の高温焼成を行っても、焼結等による粒子形態の変化は認められない薄さであり、薄板状のまましかもハニカム状の細孔の規則性を保持することが可能で、高耐熱性薄板状多孔質シリカ金属複合体粒子が提供されることになる。 Accordingly, the present inventors have developed an oxidation and reduction catalyst based on the technology developed so far by the present inventor that uses an inexpensive alkali silicate as a silica source and a non-toxic nonionic surfactant as a template. It has a metal element as an expression site in the silica skeleton, and is expected to be highly useful as a catalyst or a catalyst carrier as a chemical industry, environmental purification, food industry, medicine, or sensor. In the thin plate-like porous silica metal composite particles and the production method thereof, in which Si in the silica skeleton is substituted with another metal while maintaining the thin plate shape, and in the thin plate-like porous silica metal composite particles having the above-mentioned characteristics It is an object of the present invention to provide new technical means such as a pore diameter expansion method and the resulting large pore diameter thin plate-like porous silica metal composite particles. Furthermore, the present thin plate-like porous silica metal composite particles have such a thin thickness that no change in the particle shape due to sintering or the like is observed even when firing at a high temperature of 1000 ° C. or higher. It is possible to maintain the regularity of the pores, and to provide highly heat-resistant thin plate-like porous silica metal composite particles.
本発明者は上記の課題を解決すべく鋭意検討を進め、その過程において、強酸下においてシリカ・界面活性剤の高次構造形成能と、その高次構造を円盤状とするための金属種を厳密に選択することで、最終的に薄板状形態を有し、シリカ骨格中のSiを他金属で置換した薄板状多孔質シリカ金属複合体粒子の合成に成功した。 The present inventor has intensively studied to solve the above problems, and in the process, the ability to form a higher-order structure of silica / surfactant under a strong acid and a metal species for making the higher-order structure into a disk shape. By strict selection, the inventors finally succeeded in synthesizing thin plate-like porous silica metal composite particles that finally have a thin plate-like form and in which Si in the silica skeleton is substituted with another metal.
すなわち、従来の低コスト、低環境負荷な材料設計に基づいて、細孔構造、マクロ形態を薄板状に制御するために、無毒性で、生分解性の非イオン性界面活性剤を使用し、更にシリカ源として安価なアルカリ珪酸塩を用いた強酸性反応系における高次規則構造の形成過程と、添加する金属元素を選択することにより、反応中間生成物である薄板状多孔質シリカ金属複合粒子の前駆体となる界面活性剤を含んだ有機無機ナノ複合体を50℃以下の一定温度で生成させ、最終的に有機成分を取除くことにより、シリカ骨格中のSiを他金属元素で置換した厚さ0.5ミクロン未満の薄板状多孔質シリカ金属複合体粒子を実現した。 That is, based on conventional low-cost, low environmental load material design, non-toxic, biodegradable nonionic surfactants are used to control the pore structure and macro morphology into a thin plate, Furthermore, a thin plate-like porous silica metal composite particle that is a reaction intermediate product by selecting a metal element to be added and the formation process of a high-order ordered structure in a strongly acidic reaction system using inexpensive alkali silicate as a silica source An organic-inorganic nanocomposite containing a surfactant that is a precursor of the above is generated at a constant temperature of 50 ° C. or lower, and finally organic components are removed, whereby Si in the silica skeleton is replaced with another metal element. Thin plate-like porous silica metal composite particles having a thickness of less than 0.5 microns were realized.
さらに、50℃以下の反応温度で生成する多孔質シリカ金属複合粒子前駆体を含む懸濁液を、60℃以上のより高温において静置し熟成するだけで得られる有機無機ナノ複合体から最終的に有機成分を取除くことにより、シリカ骨格中のSiを他金属元素で置換した厚さ0.5ミクロン未満で、かつ細孔径がより大きな薄板状多孔質シリカ金属複合体粒子が製造できることを見出した。 Furthermore, the suspension containing the porous silica metal composite particle precursor produced at a reaction temperature of 50 ° C. or lower is finally obtained from the organic-inorganic nanocomposite obtained by simply standing and aging at a higher temperature of 60 ° C. or higher. It has been found that by removing organic components, a thin plate-like porous silica metal composite particle having a thickness of less than 0.5 microns and a larger pore diameter obtained by substituting Si in the silica skeleton with another metal element can be produced. It was.
本発明は以上のような全く新しい、従来では予期することのできない知見を踏まえて完成されたものである。すなわち、本発明によれば、
1.下記式
(Si1−nMn)O2
式中、Mは多価金属としてのTi又はZrを表し、
nはゼロを含まない0.1以下の数である、
で表される化学的組成を有し、走査型顕微鏡観察により薄板状粒子の薄板の厚さが0.5μm未満であり、シリケート骨格中のSi原子が多価金属Mで置換されていることを特徴とする薄板状多孔質シリカ金属複合体粒子が提供される。
本発明の薄板状多孔質シリカ金属複合体粒子においては、
2.多価金属Mによる置換によりアンモニア昇温脱離スペクトル測定によるピークが100〜400℃に存在し、固体酸性を有すること、
3.透過型電子顕微鏡観察により、薄板平面に対し垂直方向に一次元チャンネル状細孔が貫通して存在し且つチャンネル状細孔がハニカム状に規則配列していること、
4.回折角0.5乃至5度(CuKα)に細孔の規則配列構造を示すX線回折ピークを有すること、
5.前記薄板状粒子のBET比表面積が500m2/g以上且つメソ細孔径が5〜20nmの範囲にあり、全細孔容積が0.5ml/g以上を有すること
が好ましい。
The present invention has been completed on the basis of the above-mentioned completely new knowledge that could not be expected in the past. That is, according to the present invention,
1. Formula (Si 1-n M n) O 2
In the formula, M represents Ti or Zr as a polyvalent metal,
n is a number of 0.1 or less not including zero,
The thickness of the thin plate of the thin plate-like particles is less than 0.5 μm by scanning microscope observation, and the Si atom in the silicate skeleton is substituted with the polyvalent metal M. Provided are the lamellar porous silica metal composite particles.
In the lamellar porous silica metal composite particles of the present invention,
2. A peak by ammonia temperature programmed desorption spectrum measurement exists at 100 to 400 ° C. due to substitution with the polyvalent metal M, and has solid acidity,
3. By observation with a transmission electron microscope, the one-dimensional channel-shaped pores exist in a direction perpendicular to the plane of the thin plate, and the channel-shaped pores are regularly arranged in a honeycomb shape,
4). Having an X-ray diffraction peak showing a regular arrangement structure of pores at a diffraction angle of 0.5 to 5 degrees (CuKα),
5). The thin plate-like particles preferably have a BET specific surface area of 500 m 2 / g or more, a mesopore diameter of 5 to 20 nm, and a total pore volume of 0.5 ml / g or more.
また、本発明によれば、酸に溶解した非イオン性界面活性剤の溶液に、アルカリ珪酸塩水溶液を攪拌しながら混合し、生成する非イオン性界面活性剤を含んだ有機無機ナノ複合体と反応溶液との懸濁溶液に、金属塩を添加して、たとえば10秒から20分間攪拌後、攪拌を停止し、そのまま一定時間静置してメソポア多孔体前駆体を薄板状に成長させ、最終的に有機成分を除去することを特徴とする薄板状多孔質シリカ金属複合体粒子の製造方法が提供される。 Further, according to the present invention, an organic / inorganic nanocomposite containing a nonionic surfactant to be produced by mixing an aqueous alkali silicate solution with stirring into a solution of a nonionic surfactant dissolved in an acid, and Metal salt is added to the suspension solution with the reaction solution, for example, after stirring for 10 seconds to 20 minutes, the stirring is stopped, and the solution is allowed to stand for a certain period of time to grow the mesopore porous body precursor into a thin plate shape. An organic component is removed to provide a method for producing a thin plate-like porous silica metal composite particle.
すなわち、本発明の薄板状多孔質シリカ金属複合体粒子の製造方法においては、
6.酸性水溶液及び非イオン性界面活性剤の混合液に、アルカリ珪酸塩水溶液の反応温度15℃乃至50℃の温度での攪拌下の混合と多価金属としてのTi又はZrの金属塩の添加を行い、10秒〜20分間経過後、攪拌を停止し、一定時間熟成した後に得られた固形反応物中の非イオン性界面活性剤を除去することを特徴としている。そして、本発明のこの方法においては、
7.攪拌を停止し、そのまま静置するか、あるいは60〜200℃で静置して熟成させた後に固形反応物中の非イオン性界面活性剤を除去すること、
8.アルカリ珪酸塩中のSiO21モル当たり、非イオン性界面活性剤を0.01乃至0.02モルの量、酸を4乃至7モルの量、水を150乃至400モルの量、さらに金属塩を0.02乃至0.40モルの量で用いること、
が好ましい。
さらに、本発明の薄板状多孔質シリカ金属複合体粒子を850℃以上の高温で加熱して高耐熱性薄板状多孔質シリカ金属複合体粒子が得られる。
That is, in the method for producing a lamellar porous silica metal composite particle of the present invention,
6). To the mixed solution of acidic aqueous solution and nonionic surfactant, mixing with stirring at a reaction temperature of 15 ° C. to 50 ° C. of an aqueous alkali silicate solution and addition of a metal salt of Ti or Zr as a polyvalent metal After 10 seconds to 20 minutes, stirring is stopped, and the nonionic surfactant in the solid reaction product obtained after aging for a certain period of time is removed. And in this method of the invention,
7). Stop the stirring and leave it as it is or remove the nonionic surfactant in the solid reaction product after standing at 60 to 200 ° C. and aging,
8). A nonionic surfactant in an amount of 0.01 to 0.02 mol, an acid in an amount of 4 to 7 mol, an amount of water in an amount of 150 to 400 mol, and a metal salt per mol of SiO 2 in the alkali silicate In an amount of 0.02 to 0.40 mole,
Is preferred.
Furthermore, the thin plate-like porous silica metal composite particles of the present invention are heated at a high temperature of 850 ° C. or higher to obtain high heat-resistant thin plate-like porous silica metal composite particles.
すなわち、本高耐熱性薄板状多孔質シリカ金属複合体粒子においては、
9.シリケート骨格中の多価金属Mの一部あるいは全てが金属酸化物として結晶化され、薄板の厚さが0.5μm未満を維持すること、
10.透過型電子顕微鏡観察により、薄板平面に対し垂直方向に一次元チャンネル状細孔が貫通して存在し且つチャンネル状細孔がハニカム状に規則配列し、150m2/g以上
のBET比表面積を有し、且つ細孔径分布ピークが3から10nmに存在し、0.2ml/g以上の全細孔容積を有すること、
が好ましい。
That is, in the present high heat resistant lamellar porous silica metal composite particles,
9. A part or all of the polyvalent metal M in the silicate skeleton is crystallized as a metal oxide, and the thickness of the thin plate is maintained below 0.5 μm;
10. According to transmission electron microscope observation, one-dimensional channel-shaped pores exist in a direction perpendicular to the plane of the thin plate, the channel-shaped pores are regularly arranged in a honeycomb shape, and have a BET specific surface area of 150 m 2 / g or more. And having a pore size distribution peak of 3 to 10 nm and a total pore volume of 0.2 ml / g or more,
Is preferred.
そして、本発明においては、上記のとおりの薄板状多孔質シリカ金属複合体粒子について、これを用いた、樹脂または塗料用ナノコンポジット材料、フィルム状成型体用ナノコンポジット材料、吸着もしくは分離剤、光触媒またはその担体、酸化触媒またはその担体をも提供する。 And in this invention, about the thin plate-like porous silica metal composite particles as described above, a resin or paint nanocomposite material, a film-shaped nanocomposite material, an adsorption or separation agent, a photocatalyst using the same Alternatively, the support, the oxidation catalyst or the support is also provided.
本発明によれば、安価なアルカリ珪酸塩をシリカ源として用い、安全性の高い非イオン性界面活性剤をテンプレートとして使用し、更に比較的短時間で、薄板状多孔質シリカ金属複合体粒子が提供される。 According to the present invention, an inexpensive alkali silicate is used as a silica source, a highly safe nonionic surfactant is used as a template, and a thin porous silica metal composite particle is obtained in a relatively short time. Provided.
また、本発明によれば、細孔構造の制御剤として非イオン性界面活性剤を使用し、アルカリ珪酸塩水溶液と酸性水溶液を混合する極めて単純な反応系において、多孔体の前駆体となる界面活性剤を含んだ円盤状の有機無機ナノ複合体を比較的短時間で選択的に作製し、最終的に有機物を取除くことによる、薄板状シリカ多孔質粒子及びシリカ骨格中のSiを他金属で置換した薄板状多孔質シリカ金属複合体粒子の製造方法が提供される。 Further, according to the present invention, in a very simple reaction system in which a nonionic surfactant is used as a pore structure control agent and an alkali silicate aqueous solution and an acidic aqueous solution are mixed, an interface that becomes a precursor of a porous body By selectively producing a disk-shaped organic-inorganic nanocomposite containing an activator in a relatively short period of time and finally removing the organic matter, the thin plate-like silica porous particles and Si in the silica skeleton are converted to other metals. A method for producing a thin plate-like porous silica-metal composite particle substituted with is provided.
しかも、本薄板状多孔質シリカ金属複合体粒子は、薄板状形態を有すると同時に、薄板面を垂直に貫通する1次元メソチャンネル孔がハニカム状に規則配列していることが大きな特徴である。 In addition, the present thin plate-like porous silica metal composite particles have a thin plate-like form and at the same time have a great feature that the one-dimensional mesochannel holes vertically penetrating the thin plate surface are regularly arranged in a honeycomb shape.
さらに、上記常温付近、常圧下で薄板状多孔体の前駆体となる界面活性剤を含んだ有機無機ナノ複合体を、より高温下で静置・熟成することによって、細孔径の大きな薄板状多孔質シリカ金属複合体粒子並びにその製造方法が提供される。 Furthermore, by placing and aging the organic-inorganic nanocomposite containing a surfactant that becomes a precursor of a thin plate-like porous body at about normal temperature and under normal pressure, the plate-like porous material having a large pore size is obtained by standing and aging at a higher temperature. Silica metal composite particles and a method for producing the same are provided.
本発明による薄板状多孔質シリカ金属複合体粒子は、メソ孔と連結してマイクロ孔が共存する場合には、その特異な細孔構造に基づく強い吸着作用と高い粒子内拡散能を利用して、環境汚染排出ガス状物質等の浄化プロセスへの応用、あるいはゼオライトやシリカゲルに代わるシリカ系多孔体として新規用途を導くことが期待される。さらに、薄板状形態を利用することによって、樹脂添加剤、インク吸着用フィラー、増粘剤等の用途や、さらには単独乃至他の無機物質および有機化合物と混合することによりフェルト様に加工成型し、各種フィルター素材として広く利用することが可能である。特に、細孔径が広範囲に制御できることから、大きなメソ孔を利用することによって、酵素あるいは有機官能基を有する大きな分子の吸着・分離・吸蔵・固定剤等として利用することができる。また、薄板状多孔質シリカ金属複合体粒子は、シリカ骨格中の金属元素が触媒能発現の活性サイトとなり酸化触媒、還元触媒あるいはそれらの触媒担体として、光触媒等を含め種々の用途に使用できる。さらに、1000℃の高温でもハニカム状の規則配列構造を有することから、上記各種応用に際し高温環境において耐熱性多孔性材料としての利用が可能である。 The thin plate-like porous silica metal composite particles according to the present invention utilize the strong adsorption action based on the unique pore structure and the high intraparticle diffusion ability when the micropores coexist with the mesopores. It is expected to lead to new applications as a silica-based porous body that replaces zeolite and silica gel, or is applied to purification processes for environmental pollutant exhaust gases. Furthermore, by using the thin plate shape, it can be processed and molded like a felt by mixing with resin additives, ink adsorbing fillers, thickeners, etc., or alone or with other inorganic substances and organic compounds. It can be widely used as various filter materials. In particular, since the pore diameter can be controlled over a wide range, by using large mesopores, it can be used as an adsorbing / separating / occluding / fixing agent for large molecules having enzymes or organic functional groups. In addition, the thin plate-like porous silica metal composite particles can be used for various applications including photocatalysts as an oxidation catalyst, a reduction catalyst, or a catalyst carrier thereof, because the metal element in the silica skeleton becomes an active site expressing the catalytic ability. Furthermore, since it has a honeycomb-like ordered arrangement structure even at a high temperature of 1000 ° C., it can be used as a heat-resistant porous material in a high-temperature environment for the above various applications.
本発明では、ミクロンオーダーの薄板状多孔質シリカ金属複合体粒子とその製造において、シリカ源としてアルカリ珪酸塩を用い、金属アルコキシド等の高価な有機シリカを使用する必要がないこと、テンプレートとして高価な4級アンモニウム塩等を使用せずに無毒性、生分解性、安価な非イオン性界面活性剤を使用できること、また温和な温度条件下、短時間で薄板状粒子を高収率で得られること、特に添加する金属種を選択することによって、多孔質シリカ金属複合粒子を薄板状に制御できることを大きな特徴としている。そして、このような特徴は全く新規なもので、従来の技術からは予期できないものである。 In the present invention, in the micron order thin plate-like porous silica metal composite particles and the production thereof, alkali silicate is used as a silica source, it is not necessary to use expensive organic silica such as metal alkoxide, and expensive as a template. Non-toxic, biodegradable and inexpensive nonionic surfactants can be used without using quaternary ammonium salts, etc., and thin plate-like particles can be obtained in high yield in a short time under mild temperature conditions In particular, it is a great feature that the porous silica metal composite particles can be controlled in a thin plate shape by selecting a metal species to be added. Such a feature is completely new and cannot be expected from the prior art.
本発明による薄板状多孔質シリカ金属複合体粒子は、既に指摘した通り、薄板状の形状を呈すると同時に、薄板状平面に垂直に1次元メソチャンネルが貫通してハニカム状に細孔が規則配列しており、このような薄板状多孔質粒子の生成機構は以下のように推定される。 As already pointed out, the thin plate-like porous silica metal composite particles according to the present invention have a thin plate shape, and at the same time, the one-dimensional mesochannel penetrates perpendicularly to the thin plate plane and the pores are regularly arranged in a honeycomb shape. The generation mechanism of such thin plate-like porous particles is estimated as follows.
アルカリ珪酸塩は強酸性水溶液下でシリカ溶存種がプラスに帯電し[I+]、一方、強酸に溶解した非イオン性界面活性剤[N0]においても、界面活性剤表面の親水基部分がプロトン[H+]に覆われることでプラスの電荷を帯び、プラスに帯電したシリカ溶存種、界面活性剤の両表面間に陰イオン[X−]が介在することで、電気的に安定なメソ構造体[N0
H+][X−I+]を形成すると推定される。この時、非イオン性界面活性剤は自己秩序形
成能を有し、複数の分子によって構成された球状集合体がさらに高次の2次元六方晶のロッド状ミセルを形成し、シリカ溶存種が存在しても、両者間における協調的な秩序形成が進行し、ロッド状有機無機メソ構造体が生成することになる。このロッド状有機無機メソ構造体の伸張方向の長さを短く保ち、それぞれの粒子の凝集を抑制することで、薄板状の形態を有する粒子が得られることになる。有機成分を焼成或は溶媒抽出等の処理により除去することで得られる最終生成物は、薄板状形態を有すると同時に、薄板面を垂直に貫通する1次元メソチャンネル孔がハニカム状に規則配列していることになる。更に、非イオン性界面活性剤の親水性部がシリカ骨格中に進入することによりメソ孔以外にマイクロ孔も形成される。
Alkali silicate has positively charged silica dissolved species in a strongly acidic aqueous solution [I + ], while nonionic surfactant [N 0 ] dissolved in strong acid also has a hydrophilic group on the surface of the surfactant. It is positively charged by being covered with protons [H + ], and an anion [X − ] is interposed between both surfaces of the positively charged silica dissolved species and the surfactant, so that an electrically stable meso Structure [N 0
H + ] [X − I + ] is estimated to form. At this time, the nonionic surfactant has a self-ordering ability, and a spherical aggregate composed of a plurality of molecules forms higher-order two-dimensional hexagonal rod-like micelles, and silica dissolved species exist. Even so, cooperative order formation between the two proceeds, and a rod-shaped organic-inorganic mesostructure is generated. By keeping the length of the rod-like organic / inorganic mesostructure in the extension direction short and suppressing aggregation of the respective particles, particles having a thin plate shape can be obtained. The final product obtained by removing the organic components by a process such as firing or solvent extraction has a thin plate shape, and at the same time, one-dimensional mesochannel holes vertically penetrating the thin plate surface are regularly arranged in a honeycomb shape. Will be. Furthermore, micropores are formed in addition to mesopores when the hydrophilic portion of the nonionic surfactant enters the silica skeleton.
上記ロッド状有機無機メソ構造体の厚さは、反応温度を比較的低く設定することで可能であるが、金属塩を添加しない、純粋なシリカ系の薄板状多孔質粒子の厚さを0.5μm未満にすることは難しい。 The thickness of the rod-shaped organic-inorganic mesostructure can be set by setting the reaction temperature relatively low. However, the thickness of pure silica-based thin plate-like porous particles to which no metal salt is added is set to 0. It is difficult to make it less than 5 μm.
本発明では、非イオン性界面活性剤の高次構造として薄いロッド状ミセル集合体、すなわち円盤状の集合体を形成させる目的で、種々の金属塩を添加し、その効果を検討した。その結果、多くの金属塩はロッド状有機無機メソ構造体を伸張させる逆の効果を示すことを見出すと共に、数種類の金属塩はロッド状構造体の伸張を抑制すると同時に、比較的高温においても同様な効果を発揮することを明らかにした。さらに、この抑制効果をもたらす金属元素は酸性条件下においてもシリカ骨格中のSiを置換する能力を有することを明らかにできた。本発明においては、上記の複合的な効果を利用することによって、シリカ骨格中のSiを金属元素で置換した、薄板状多孔質シリカ金属複合体粒子が合成できることを見出した。 In the present invention, various metal salts were added for the purpose of forming a thin rod-like micelle aggregate, that is, a disc-like aggregate, as a higher-order structure of a nonionic surfactant, and the effect was examined. As a result, many metal salts have been found to have the opposite effect of stretching the rod-like organic-inorganic mesostructure, and several types of metal salts suppress the elongation of the rod-like structure and at the same time at relatively high temperatures. It was clarified that it exerts a good effect. Furthermore, it was clarified that the metal element that brings about this suppression effect has the ability to substitute Si in the silica skeleton even under acidic conditions. In the present invention, it has been found that by using the above composite effect, thin plate-like porous silica metal composite particles in which Si in the silica skeleton is substituted with a metal element can be synthesized.
さらに、金属塩の添加により生成する円盤状構造体は50〜60℃では一般に伸張してロッド状構造体に変化するが、温度の上昇により伸張が抑制され再度円盤状構造体となり、この場合非イオン性界面活性剤の親水基がより疎水性を帯びることから、最終的に大きなメソ細孔の形成を可能とすると考えられる。 Further, the disk-like structure formed by adding the metal salt generally stretches and changes to a rod-like structure at 50 to 60 ° C., but the extension is suppressed due to the rise in temperature and becomes a disk-like structure again. Since the hydrophilic group of the ionic surfactant is more hydrophobic, it is thought that it is possible to finally form a large mesopore.
なお、有機無機メソ構造体を構成する界面活性剤の親水基はシリカ骨格内に侵入しており、その除去に伴いマイクロ孔形成の要因となり、薄板状多孔質シリカ金属複合体粒子は独特のマクロ形態と、メソ孔とマイクロ孔を併せ持つことになる。しかも、メソ孔は薄板面に垂直にハニカム状に規則配列している。ただし、高温になるほど親水基は疎水性を帯びマイクロ孔の形成が抑制されるようになる。 The hydrophilic group of the surfactant that constitutes the organic / inorganic mesostructure penetrates into the silica skeleton, and as a result of the removal, microporous formation occurs, and the thin plate-like porous silica metal composite particles have a unique macro. It will have both morphology and mesopores and micropores. In addition, the mesopores are regularly arranged in a honeycomb shape perpendicular to the thin plate surface. However, the higher the temperature, the more hydrophilic groups become hydrophobic and the formation of micropores is suppressed.
図1A及び図1Bは、後述の実施例において例示したそれぞれTiとZrを含有する場合の本発明の薄板状多孔質シリカ金属複合体粒子の走査電子顕微鏡写真である。いずれも幅1ミクロン、厚さ約0.3〜0.4ミクロンの六角薄板状粒子が強く凝集しない状態で存在していることがわかる。 FIG. 1A and FIG. 1B are scanning electron micrographs of the lamellar porous silica metal composite particles of the present invention when Ti and Zr are respectively exemplified in the examples described later. It can be seen that hexagonal thin plate-like particles having a width of 1 micron and a thickness of about 0.3 to 0.4 micron are present without being strongly aggregated.
たとえばこのように、本発明の薄板状多孔質シリカ金属複合体粒子においては、走査型電子顕微鏡観察により薄板状粒子の薄板の厚さが0.5μm未満であり、シリケート骨格中のSi原子がTiをはじめとする各種の多価金属Mで置換され、前記のとおりの(Si1-nMn)O2の化学組成を有している。ここで、係数nは0.1以下の数である。たとえば、後述の実施例として示した表1においては金属含有両の値を100で割った値として、この係数nは、薄板状では0.011〜0.047となる。 For example, as described above, in the thin plate-like porous silica metal composite particles of the present invention, the thickness of the thin plate-like particles is less than 0.5 μm by scanning electron microscope observation, and Si atoms in the silicate skeleton are Ti. And the chemical composition of (Si 1-n M n ) O 2 as described above. Here, the coefficient n is a number of 0.1 or less. For example, in Table 1 shown as an example to be described later, this coefficient n is 0.011 to 0.047 in a thin plate shape as a value obtained by dividing both values of metal content by 100.
図2は、図1に示した本発明の薄板状多孔質シリカ金属複合体粒子のそれぞれの透過型電子顕微鏡写真である。いずれも、薄板状平面に垂直に1次元メソチャンネルが貫通し且つこのチャンネル状細孔がハニカム状に規則配列していることがわかる。 FIG. 2 is a transmission electron micrograph of each of the thin plate-like porous silica metal composite particles of the present invention shown in FIG. In either case, it can be seen that the one-dimensional mesochannels penetrate perpendicularly to the thin plate-like plane and the channel-shaped pores are regularly arranged in a honeycomb shape.
本発明の薄板状多孔質シリカ金属複合体粒子は、シリケート骨格中のSiを他の金属原子で置換したことに起因して固体酸性を有する。図3、図7および図8は、Ti、Zrを含有する場合の本発明の薄板状多孔質シリカ金属複合体粒子について例示したアンモニア昇温脱離スペクトルである。脱離ピークがいずれの場合も100〜400℃に存在することから、金属サイトに起因する固体酸性が発現することがわかる。 The thin plate-like porous silica metal composite particles of the present invention have solid acidity due to substitution of Si in the silicate skeleton with other metal atoms. 3, 7 and 8 are ammonia thermal desorption spectra exemplified for the thin plate-like porous silica metal composite particles of the present invention when Ti and Zr are contained. Since the desorption peak is present at 100 to 400 ° C. in any case, it is understood that solid acidity due to the metal site is expressed.
また、図4は、本発明のTiをシリカ骨格中に含む薄板状多孔質シリカ金属複合体粒子の紫外可視分光スペクトルである。220nmの顕著なピークは、シリケート骨格中のSiがTiによって置換されたことを明示するものである。 FIG. 4 is an ultraviolet-visible spectrum of the thin plate-like porous silica metal composite particles containing Ti of the present invention in the silica skeleton. The remarkable peak at 220 nm clearly shows that Si in the silicate skeleton was replaced by Ti.
図5および図11は、本発明の薄板状多孔質シリカ金属複合体粒子の粉末X線回折パターン(X線源:CuKα)で、回折角2θ=0.5乃至5.0度にメソ孔の規則配列を示す複数のピークが認められる。 FIG. 5 and FIG. 11 are powder X-ray diffraction patterns (X-ray source: CuKα) of the thin plate-like porous silica metal composite particles of the present invention, with mesopores at a diffraction angle 2θ = 0.5 to 5.0 degrees. A plurality of peaks showing a regular arrangement are observed.
本発明の薄板状多孔質シリカ金属複合体粒子は、いずれもIV型の吸着等温線を持ち、一次粒子内にメソ孔を持つこと、さらに図6、図9および図10の細孔径分布曲線(BJH法)からシャープな細孔径分布を有していることが明らかで、本細孔特性評価はXRD回折並びにTEM像の結果からも裏付けられる。そして、本発明によれば、薄板状粒子のBET比表面積が500m2/g以上で、かつ、メソ細孔径が5〜20nmの範囲にあり
、全細孔容積が0.5ml/g以上を有する多孔質シリカ金属複合体粒子が提供される。
Each of the thin plate-like porous silica metal composite particles of the present invention has an IV type adsorption isotherm, has mesopores in the primary particles, and pore diameter distribution curves (FIG. 6, FIG. 9 and FIG. 10). It is clear from the BJH method) that this has a sharp pore size distribution, and this pore characteristic evaluation is supported by the results of XRD diffraction and TEM images. According to the present invention, the BET specific surface area of the thin plate-like particles is 500 m 2 / g or more, the mesopore diameter is in the range of 5 to 20 nm, and the total pore volume is 0.5 ml / g or more. Porous silica metal composite particles are provided.
さらに、図12AのTEM像は、本薄板状多孔質シリカ金属複合体粒子が、たとえば1000℃の高温においてもハニカム状に規則配列した細孔構造を保持することを明示するもので、このことは図13AのXRD回折パターンに複数のピークが認められることから支持される。また、図12BのTEM像から、高温焼成によりSiと置換していたZrがZrO2として結晶化し、5nm以下のナノ粒子としてシリカマトリックス中に高分散状態で存在することが分かる。ZrO2ナノ粒子の存在状態は、図13BのXRD回折パターンのブロードなピークとして認められる。 Furthermore, the TEM image in FIG. 12A clearly shows that the thin plate-like porous silica metal composite particles maintain a pore structure regularly arranged in a honeycomb shape even at a high temperature of, for example, 1000 ° C. This is supported by the fact that a plurality of peaks are observed in the XRD diffraction pattern of FIG. 13A. From the TEM image of FIG. 12B, it can be seen that Zr substituted with Si by high-temperature baking crystallizes as ZrO 2 and exists in a highly dispersed state in the silica matrix as nanoparticles of 5 nm or less. The presence state of ZrO 2 nanoparticles is recognized as a broad peak in the XRD diffraction pattern of FIG. 13B.
マイクロ孔に関しては、製造方法の具体的形態によっても制御されることになる。たとえば製造方法については、その代表的な形態として、酸性水溶液及び非イオン性界面活性剤の混合液に、反応温度15℃〜50℃の範囲において、
<A>アルカリ珪酸塩水溶液を攪拌下に混合し、その後直ちに多価金属の金属塩を添加し、10秒〜20分間後に攪拌を停止し、そのままの温度で一定時間熟成した後に、もしくは、
<B>アルカリ珪酸塩水溶液を攪拌下に混合しながら多価金属の金属塩を添加し、10秒〜20分間後に攪拌を停止し、60℃〜200℃の温度範囲に静止して一定時間熟成した後に、得られた固形反応物中の非イオン性界面活性剤を除去する方法が示される。
The micropores are also controlled by the specific form of the manufacturing method. For example, with respect to the production method, as a typical form thereof, a mixed solution of an acidic aqueous solution and a nonionic surfactant is used in a reaction temperature range of 15 ° C to 50 ° C.
<A> The alkali silicate aqueous solution is mixed with stirring, and then the metal salt of the polyvalent metal is immediately added, and the stirring is stopped after 10 seconds to 20 minutes, after aging for a certain time at the same temperature, or
<B> Add a metal salt of a polyvalent metal while mixing an aqueous alkali silicate solution with stirring, stop stirring after 10 seconds to 20 minutes, and stand still in a temperature range of 60 ° C. to 200 ° C. for aging for a certain period of time. After that, a method for removing the nonionic surfactant in the obtained solid reactant is shown.
前者の<A>製造方法(表1)では全細孔容積の内0.08ml以上の細孔容積を有する。一方、<B>製造方法(表2)では、細孔特性は熟成温度に顕著に依存すること、また含有される金属元素による依存度の差異が明瞭である。Zrを含む場合には、特にマイクロ孔容積は熟成温度の上昇によって著しい減少が認められるが、細孔径は10nm以上で全細孔容積は1ml/g以上と大きな値を示す。 The former <A> production method (Table 1) has a pore volume of 0.08 ml or more of the total pore volume. On the other hand, in the <B> production method (Table 2), the pore characteristics remarkably depend on the aging temperature, and the difference in the degree of dependence depending on the contained metal element is clear. When Zr is contained, the micropore volume is particularly markedly decreased with an increase in the aging temperature, but the pore diameter is 10 nm or more and the total pore volume is as large as 1 ml / g or more.
本発明における多価金属については、シリケートのSi原子を置換するものとして各種であってよいが、代表的には、原子価4をとるTi,Zrや、原子価3〜5をとるCr,V,MnあるいはSn,Ge,等が好適なものとして例示される。 The polyvalent metal in the present invention may be variously substituted for the Si atom of the silicate, but typically, Ti and Zr having a valence of 4 and Cr and V having a valence of 3 to 5 are used. , Mn, Sn, Ge, etc. are exemplified as suitable ones.
本発明の製造方法について説明すると、まず、酸性水溶液及び非イオン性界面活性剤の混合液に、アルカリ珪酸塩水溶液を15℃〜50℃の範囲で攪拌下に混合する。また、この混合後、もしくは混合しながら多価金属の金属塩を添加する。そしてその添加終了後に10秒〜20分間経過した後に攪拌を停止する。この停止後に静止して得られる固形反応物中の非イオン性界面活性剤を除去する。 The production method of the present invention will be described. First, an alkali silicate aqueous solution is mixed in a mixed solution of an acidic aqueous solution and a nonionic surfactant with stirring in a range of 15 ° C to 50 ° C. Further, a metal salt of a polyvalent metal is added after this mixing or while mixing. And stirring is stopped after 10 second-20 minutes have passed after the addition completion. After the stop, the nonionic surfactant in the solid reactant obtained by standing still is removed.
図14Aは、金属塩を添加せず25℃で得られた純粋な薄板状シリカ多孔質粒子のSEM像であり、反応温度が低い場合にも、厚さ0.5ミクロン以下の薄板状に制御することは難しい。また、図14Bは、純粋なシリカ多孔質粒子の場合、わずかに反応温度を上げるだけで薄板状からロッド状に変化してしまうことを示している。一方、図1Aは比較的高い温度である36℃で得られた薄板状多孔質シリカ金属複合体粒子であり、さらに図1Bは25℃で生成する反応中間体を150℃で熟成して得られた薄板状多孔質シリカ金属複合体粒子であり、金属塩の添加が薄板状粒子の厚さを減少させるために極めて有効であることを明示している。 FIG. 14A is an SEM image of pure lamellar silica porous particles obtained at 25 ° C. without addition of a metal salt. Even when the reaction temperature is low, it is controlled to a lamellar thickness of 0.5 μm or less. Difficult to do. FIG. 14B shows that pure silica porous particles change from a thin plate shape to a rod shape with a slight increase in reaction temperature. On the other hand, FIG. 1A is a thin plate-like porous silica metal composite particle obtained at a relatively high temperature of 36 ° C., and FIG. 1B is obtained by aging a reaction intermediate produced at 25 ° C. at 150 ° C. It is clearly shown that the addition of a metal salt is extremely effective for reducing the thickness of the thin plate-like particles.
本発明の製造法においては、純粋な薄板状多孔質シリカ粒子は比較的低温下でしか生成しないが、金属塩の添加によって薄板状粒子の生成温度範囲が広くなると同時に厚さも薄くなることが大きな特徴である。金属塩の添加時間は、生成物の凝集状態に影響を及ぼすが、反応開始(2種類の反応溶液の混合時点)から、10分を超えて添加すると、薄板状粒子は凝集するものの、大きなフロックに成長することはない。金属塩の添加量も、薄板状粒子の厚さ、凝集状態に大きな影響を及ぼし、少なすぎても過剰であっても凝集し易くなると同時に薄板が厚くなる傾向が認められる。また、反応温度も薄板状粒子の厚さ、凝集状態に大きな影響を及ぼす。攪拌と熟成を同一温度で行う場合には、その温度が高すぎると凝集し易くなると同時に薄板も厚くなり易い。一方、熟成温度を攪拌時よりも高くすると、薄板状粒子が得られるようになり比較的凝集の程度が弱くなる傾向がある。 In the production method of the present invention, pure lamellar porous silica particles are produced only at a relatively low temperature. However, the addition of a metal salt broadens the production temperature range of the lamellar particles and at the same time reduces the thickness. It is a feature. The addition time of the metal salt affects the aggregation state of the product, but if it is added over 10 minutes from the start of the reaction (at the time of mixing the two kinds of reaction solutions), the lamellar particles aggregate, but a large floc Never grow up. The addition amount of the metal salt also has a great influence on the thickness and aggregation state of the thin plate-like particles, and it tends to be easy to agglomerate if it is too little or excessive, and at the same time, the tendency of the thin plate to become thick is recognized. In addition, the reaction temperature has a great influence on the thickness and aggregation state of the thin plate-like particles. When stirring and ripening are carried out at the same temperature, if the temperature is too high, agglomeration is likely to occur, and at the same time, the thin plate tends to be thick. On the other hand, when the aging temperature is higher than that during stirring, thin plate-like particles can be obtained and the degree of aggregation tends to be relatively weak.
本製造法において、規則的に配列したメソ孔を有する薄板状多孔質シリカ金属複合体粒子の前駆体を、15〜50℃の常圧下において短時間で製造できる。特に、本製造法においては、シリカ骨格中のSiを他金属で置換した薄板状多孔質シリカ金属複合体粒子が得られ、金属種によって細孔径、細孔容積等の制御が可能である。さらに、前記の特徴を有する薄板状多孔質シリカ金属複合体粒子において細孔径の拡張法等の新しい技術手段と、その結果得られる大細孔径薄板状多孔質シリカ金属複合体粒子が提供される。 In this production method, the precursor of the thin plate-like porous silica metal composite particles having regularly arranged mesopores can be produced in a short time under a normal pressure of 15 to 50 ° C. In particular, in this production method, thin plate-like porous silica metal composite particles in which Si in the silica skeleton is substituted with another metal can be obtained, and the pore diameter, pore volume, and the like can be controlled by the metal species. Furthermore, there are provided new technical means such as a method for expanding the pore diameter in the thin plate-like porous silica metal composite particles having the above characteristics, and the resulting large pore diameter thin plate-like porous silica metal composite particles.
本発明の薄板状多孔質シリカ金属複合体粒子は、所定の濃度の酸に溶解した非イオン性界面活性剤溶液と、水で希釈したアルカリ珪酸塩水溶液を攪拌下に混合し一定時間経過後、金属塩を添加した後、攪拌を停止し、一定時間静置することにより、非イオン性界面活性剤とシリカ及び金属溶存種との協調的秩序形成能に基づいて生成する非イオン性界面活性剤を包含したシリカ金属複合体である多孔体前駆体から、最終的に非イオン性界面活性剤を焼成或は溶媒抽出等の手段により除去することで作製される。 The thin plate-like porous silica metal composite particles of the present invention are mixed with a nonionic surfactant solution dissolved in an acid of a predetermined concentration and an alkali silicate aqueous solution diluted with water under stirring, and after a certain period of time, After adding the metal salt, stirring is stopped, and the mixture is allowed to stand for a certain period of time, thereby generating a nonionic surfactant based on the ability to form a coordinated order between the nonionic surfactant and silica and dissolved metal species. It is produced by finally removing the nonionic surfactant from the porous precursor, which is a silica metal composite including the above, by means such as baking or solvent extraction.
さらに、本薄板状多孔質シリカ金属複合体粒子は、850℃以上の高温焼成を行っても、焼結等による粒子形態の変化は認められない薄さであり、薄板状のまましかもハニカム状の細孔の規則性を保持することが可能で、高耐熱性薄板状多孔質シリカ金属複合体粒子が提供されることになる。この場合の焼成温度としては850℃〜1500℃の範囲が好適に考慮される。さらには950℃〜1200℃の範囲が考慮される。
[原料]
本発明で使用される、シリカ原料、非イオン性界面活性剤、酸、及び金属塩について更に説明する。
Furthermore, the present thin plate-like porous silica metal composite particles are thin so that no change in the particle shape due to sintering or the like is observed even when firing at a high temperature of 850 ° C. or higher. It is possible to maintain the regularity of the pores, and to provide highly heat-resistant thin plate-like porous silica metal composite particles. A range of 850 ° C. to 1500 ° C. is suitably considered as the firing temperature in this case. Furthermore, a range of 950 ° C. to 1200 ° C. is considered.
[material]
The silica raw material, nonionic surfactant, acid, and metal salt used in the present invention will be further described.
本発明で使用されるシリカ原料としては、アルカリ珪酸塩を使用することが可能で、比較的廉価であるナトリウム珪酸塩が好ましい。ナトリウム珪酸塩としてはNa2O・mSiO2式中、mは1乃至4の数、特に2.5乃至3.5の数である組成を有するナトリウム珪酸塩水溶液を使用することが好ましい。 As the silica raw material used in the present invention, alkali silicate can be used, and sodium silicate which is relatively inexpensive is preferable. As the sodium silicate, it is preferable to use a sodium silicate aqueous solution having a composition in which Na is a number of 1 to 4, particularly 2.5 to 3.5, in the Na 2 O · mSiO 2 formula.
非イオン性界面活性剤としては、ポリエチレンオキシド(PEO)を含む高分子界面活性剤が使用でき、特にPEOを含むトリブロック共重合体が好ましく、さらにはポリエチレンオキシドーポリプロピレンオキシド-ポリエチレンオキシド(PEO−PPO−PE
O)の使用が最適である。
As the nonionic surfactant, a polymer surfactant containing polyethylene oxide (PEO) can be used, and a triblock copolymer containing PEO is particularly preferable. Further, polyethylene oxide-polypropylene oxide-polyethylene oxide (PEO-) is preferable. PPO-PE
The use of O) is optimal.
本発明で使用される、トリブロック共重合体の重合比、平均分子量並びに疎水基の重量割合が重要であり、その平均分子量は約4800以上で、疎水基の重量割合が、重量65%以上であることが望ましい。 The polymerization ratio, average molecular weight, and weight ratio of the hydrophobic group used in the present invention are important. The average molecular weight is about 4800 or more, and the weight ratio of the hydrophobic group is 65% or more. It is desirable to be.
本発明で使用される金属塩として、シリカ骨格中のSiを強酸性下で置換することにできるTi、Zr、V等を含む塩化物、硝酸塩、硫酸塩、オキソ酸素酸塩が利用できる。 As metal salts used in the present invention, chlorides, nitrates, sulfates and oxooxyacids containing Ti, Zr, V, etc., which can replace Si in the silica skeleton under strong acidity can be used.
酸としては、塩酸、硫酸、硝酸、酢酸等が使用できる。 As the acid, hydrochloric acid, sulfuric acid, nitric acid, acetic acid and the like can be used.
本発明の薄板状多孔質シリカ金属複合体粒子の合成において、出発原料の混合モル比は、SiO2:非イオン性界面活性剤:酸:金属塩:水 =1:0.01〜0.02:4〜7:0.02〜0.4:150〜400であるのが好ましい。 In the synthesis of the thin plate-like porous silica metal composite particles of the present invention, the mixing molar ratio of the starting materials is as follows: SiO 2 : nonionic surfactant: acid: metal salt: water = 1: 0.01 to 0.02. : 4-7: 0.02-0.4: 150-400 is preferable.
更に、出発原料の混合方式を詳細に記述すると、薄板状多孔質シリカ金属複合体粒子合成においては、所定の濃度の酸に溶解した非イオン性界面活性剤溶液(A)に、水に希釈したアルカリ珪酸塩水溶液(B)を攪拌下で添加する。原料溶液A及びBは予め同じ所定温度に調整して混合し、攪拌しながら20秒〜5分後に金属塩の添加し、20秒から20分経過後攪拌を停止する。ここで、攪拌と静置反応を同一温度で行う場合、15〜50℃、さらに好ましくは20〜40℃で2時間から24時間静置して熟成を行う。一方、攪拌時より高温で静置反応を行う場合には、攪拌停止後反応容器をそのまま昇温するか、あるいは一定温度に保持した恒温装置に反応容器を移動し、60〜200℃、さらに好ましくは70〜180℃で30分から10時間静置し熟成する。 Further, the mixing method of the starting materials will be described in detail. In the synthesis of the thin plate-like porous silica metal composite particles, the nonionic surfactant solution (A) dissolved in a predetermined concentration of acid was diluted with water. An aqueous alkali silicate solution (B) is added with stirring. The raw material solutions A and B are adjusted to the same predetermined temperature and mixed in advance, and the metal salt is added after 20 seconds to 5 minutes while stirring, and the stirring is stopped after 20 seconds to 20 minutes. Here, in the case where the stirring and the standing reaction are performed at the same temperature, the maturing is performed by standing at 15 to 50 ° C., more preferably 20 to 40 ° C. for 2 to 24 hours. On the other hand, when the stationary reaction is performed at a temperature higher than that during stirring, the temperature of the reaction container is increased as it is after the stirring is stopped, or the reaction container is moved to a constant temperature apparatus maintained at a constant temperature, and is preferably 60 to 200 ° C. Is aged at 70-180 ° C. for 30 minutes to 10 hours.
上記いずれの場合も、反応後懸濁液から固体生成物を分離し、室温〜100℃で充分乾燥させる。最後に有機成分を除去して薄板状多孔質シリカ金属複合体粒子を作製するために、200℃以上で2時間以上、好ましくは400℃以上で1時間加熱処理する。
[用途]
本発明による薄板状多孔質シリカ金属複合体粒子は、メソ孔と連結してマイクロ孔が共存する場合には、その特異な細孔構造に基づく強い吸着作用と高い粒子内拡散能を利用して、環境汚染排出ガス状物質等の浄化プロセスへの応用、あるいはゼオライトやシリカゲルに代わるシリカ系多孔体として新規用途を導くことが期待される。さらに、薄板状形態を利用することによって、樹脂添加剤、インク吸着用フィラー、増粘剤等の用途や、さらには単独乃至他の無機物質および有機化合物と混合することによりフェルト様に加工成型し、各種フィルター素材として広く利用することが可能である。特に、細孔径が広範囲に制御できることから、大きなメソ孔を利用することによって、酵素あるいは有機官能基を有する大きな分子の吸着・分離・吸蔵・固定剤等として利用することができる。さらに、薄板状多孔質シリカ金属複合体粒子は、シリカ骨格中の金属元素が触媒能発現の活性サイトとなり酸化触媒、還元触媒あるいはそれらの触媒担体として、光触媒等を含め種々の用途に使用できる。さらに、850℃以上、たとえば1000℃の高温でもハニカム状の規則配列構造を有することから、上記各種応用に際し高温環境において耐熱性多孔性材料としての利用が可能である。
In any of the above cases, the solid product is separated from the suspension after the reaction and sufficiently dried at room temperature to 100 ° C. Finally, in order to remove the organic component and produce the thin plate-like porous silica metal composite particles, heat treatment is performed at 200 ° C. or higher for 2 hours or longer, preferably 400 ° C. or higher for 1 hour.
[Usage]
The thin plate-like porous silica metal composite particles according to the present invention utilize the strong adsorption action based on the unique pore structure and the high intraparticle diffusion ability when the micropores coexist with the mesopores. It is expected to lead to new applications as a silica-based porous body that replaces zeolite and silica gel, or is applied to purification processes for environmental pollutant exhaust gases. Furthermore, by using the thin plate shape, it can be processed and molded like a felt by mixing with resin additives, ink adsorbing fillers, thickeners, etc., or alone or with other inorganic substances and organic compounds. It can be widely used as various filter materials. In particular, since the pore diameter can be controlled over a wide range, by using large mesopores, it can be used as an adsorbing / separating / occluding / fixing agent for large molecules having enzymes or organic functional groups. Furthermore, the thin plate-like porous silica-metal composite particles can be used for various applications including photocatalysts as oxidation catalysts, reduction catalysts, or catalyst carriers thereof as the active sites for the expression of catalytic activity by the metal elements in the silica skeleton. Furthermore, since it has a honeycomb-like ordered arrangement structure even at a high temperature of 850 ° C. or higher, for example, 1000 ° C., it can be used as a heat-resistant porous material in a high-temperature environment for the above various applications.
次に、本発明を実施例によって更に具体的に説明するが、本発明はこの実施例によって限定されない。 EXAMPLES Next, although an Example demonstrates this invention further more concretely, this invention is not limited by this Example.
尚、実施例で行った各試験方法は次の方法により行った。
(測定法)
(1)走査型電子顕微鏡:日本電子株式会社製JSM5300を使用し、加速電圧10kV、WD10mmで観察した。
(2)比表面積・細孔径分布:日本ベル製BELSORP28を使用し、液体窒素温度で測定した窒素吸着等温線からBET比表面積を求め、細孔容積はt−プロット法により求め、細孔径分布はBJH法により解析した。
(3)形状:走査型電子顕微鏡写真から観察した。
(4)粒子サイズ:走査型電子顕微鏡写真で測定した。
(5)X線回折:リガク製ロータフレックスRU−300を使用し、CuKα線源、加速電圧40kV、80mAで測定した。
(6)高分解能電子顕微鏡:HITACHI製HF-2000を使用し、加速電圧200
kVで観察した。
(7)化学分析:試料を1000℃、2時間強熱した後、アルカリ溶融後、誘導結合プラズマ発光分析法(ICP-AES法)にて金属元素並びにSi含有量を測定した。
(8)紫外可視分光光度計:島津製作所製UV-2500を使用し、積分球方式による拡散反射
測定をBaSO4を標準物質として測定した。
(実施例1)
水を加えて希釈した市販のJIS3号珪酸ナトリウム(SiO2:23.6%、Na2O:7.59%)を、2Nの塩酸に溶解したトリブロック共重合体Pluronic
P123 (PE
O20PPO70PEO20)(平均分子量5800)(Aldrich)溶液に攪拌しながら添加
する。両原料溶液は予め所定温度37℃に調整して混合する(反応開始点)。両原料溶液を混合後素早く直ちに塩化チタン(TiCl4)を添加する。添加してから、1分間で攪拌を停止して、反応開始点から6時間反応させた。混合溶液のモル比はSiO2:Pluronic
P123:Na2O:HCl:H2O=1:0.017:0.312:5.88:201
.5であり、TiCl4の同モル比は0.18(実施例1−1)、0.45(実施例1−2)及び0.89(実施例1−3)である。尚、H2Oには全ての原料由来の水が含まれている。反応後固体生成物を濾別し、洗浄後、50℃で十分乾燥させる。最終的に600℃の電気炉中で1時間焼成を行うことで有機成分を除去し薄板状Ti含有多孔質シリカ金属複合体粒子を得る。
In addition, each test method performed in the Example was performed by the following method.
(Measurement method)
(1) Scanning electron microscope: JSM5300 manufactured by JEOL Ltd. was used and observed at an acceleration voltage of 10 kV and a WD of 10 mm.
(2) Specific surface area / pore size distribution: BELSORP28 manufactured by Nippon Bell Co., Ltd. was used to determine the BET specific surface area from the nitrogen adsorption isotherm measured at liquid nitrogen temperature, the pore volume was determined by the t-plot method, Analysis was performed by the BJH method.
(3) Shape: Observed from scanning electron micrograph.
(4) Particle size: measured by scanning electron micrograph.
(5) X-ray diffraction: Rigaku Rotorflex RU-300 was used and measured with a CuKα radiation source, an acceleration voltage of 40 kV, and 80 mA.
(6) High-resolution electron microscope: HITACHI HF-2000 is used and acceleration voltage is 200
Observed at kV.
(7) Chemical analysis: The sample was ignited at 1000 ° C. for 2 hours, and after alkali melting, the metal element and Si content were measured by inductively coupled plasma emission spectrometry (ICP-AES method).
(8) UV-visible spectrophotometer: Shimadzu UV-2500 was used, and diffuse reflection measurement by an integrating sphere method was measured using BaSO 4 as a standard substance.
Example 1
Commercially available JIS No. 3 sodium silicate (SiO 2 : 23.6%, Na 2 O: 7.59%) diluted with water was dissolved in 2N hydrochloric acid, a triblock copolymer Pluronic.
P123 (PE
O 20 PPO 70 PEO 20 ) (average molecular weight 5800) (Aldrich) is added with stirring. Both raw material solutions are adjusted in advance to a predetermined temperature of 37 ° C. and mixed (reaction starting point). Titanium chloride (TiCl 4 ) is added immediately after mixing both raw material solutions. After the addition, stirring was stopped in 1 minute, and the reaction was allowed to proceed for 6 hours from the reaction start point. The molar ratio of the mixed solution is SiO 2 : Pluronic
P123: Na 2 O: HCl: H 2 O = 1: 0.017: 0.312: 5.88: 201
. The same molar ratio of TiCl 4 is 0.18 (Example 1-1), 0.45 (Example 1-2), and 0.89 (Example 1-3). H 2 O contains water derived from all raw materials. After the reaction, the solid product is filtered off, washed and sufficiently dried at 50 ° C. Finally, the organic component is removed by firing in an electric furnace at 600 ° C. for 1 hour to obtain thin plate-like Ti-containing porous silica metal composite particles.
図1Aは、本実施例1−2の薄板状Ti含有多孔質シリカ金属複合体粒子の走査電子顕微鏡写真である。幅1ミクロン、厚さ0.3〜0.4ミクロンの六角薄板状粒子が比較的良く分散して存在していることがわかる。 FIG. 1A is a scanning electron micrograph of the thin plate-like Ti-containing porous silica metal composite particles of Example 1-2. It can be seen that hexagonal thin plate-like particles having a width of 1 micron and a thickness of 0.3 to 0.4 micron are relatively well dispersed.
図2Aは、本実施例1−2の薄板状Ti含有多孔質シリカ金属複合体粒子の透過型電子顕微鏡写真である。薄板状平面に垂直に約5nmの1次元メソチャンネルが貫通し且つハニカム状に規則配列していることが明らかである。 FIG. 2A is a transmission electron micrograph of the thin plate-like Ti-containing porous silica metal composite particles of Example 1-2. It is clear that one-dimensional mesochannels of about 5 nm pass through perpendicular to the thin plate-like plane and are regularly arranged in a honeycomb shape.
図3は本実施例のアンモニア昇温脱離スペクトルであり、Ti含有量が多くなるほど、脱離量が多いことから固体酸量が大きく、さらにピーク位置がやや高温側にシフトすることから酸強度が強くなることがわかる。 FIG. 3 is an ammonia temperature-programmed desorption spectrum of the present example. The greater the Ti content, the greater the desorption amount, the greater the amount of solid acid, and the peak position shifts slightly to the higher temperature side. It turns out that becomes stronger.
図4は本実施例の紫外可視分光スペクトルであり、いずれも220nmに顕著なピークが認められ、しかもTi含有量が増加しても260nm付近にブロードなショルダーピークが存在せず、シリケート骨格中のSiがTiによって置換され、Tiは4配位で存在することがわかる。 FIG. 4 is an ultraviolet-visible spectroscopic spectrum of the present example, in which a remarkable peak is observed at 220 nm, and even when the Ti content is increased, a broad shoulder peak does not exist in the vicinity of 260 nm. It can be seen that Si is replaced by Ti, and Ti exists in a tetracoordinate configuration.
図5は、本実施例の薄板状シリカ金属複合体粒子の粉末X線回折パターン(X線源はCuKα)で、回折角2θ=0.5乃至5.0度にメソ孔の規則配列を示す複数のピークが認められる。 FIG. 5 is a powder X-ray diffraction pattern (X-ray source is CuKα) of the lamellar silica metal composite particles of this example, and shows a regular arrangement of mesopores at a diffraction angle 2θ = 0.5 to 5.0 degrees. Multiple peaks are observed.
図6は、本発明の薄板状Ti含有多孔質シリカ金属複合体粒子の細孔径分布曲線である。 FIG. 6 is a pore size distribution curve of the thin plate-like Ti-containing porous silica metal composite particles of the present invention.
表1に本実施例の薄板状Ti含有多孔質シリカ金属複合体粒子中のTiモル%、BET比表面積、全細孔容積、マイクロ孔容積、さらに固体酸量を示す。
(実施例2)
水を加えて希釈した市販のJIS3号珪酸ナトリウム(SiO2:23.6%、Na2O:7.59%)を、2Nの塩酸に溶解したトリブロック共重合体Pluronic
P123 (PE
O20PPO70PEO20) (平均分子量5800)(Aldrich)溶液に攪拌しながら添加
する。両原料溶液は予め所定温度25℃に調整して混合し(反応開始点)、両原料溶液を混合後素早く塩化チタンを添加してから、1分間で攪拌を停止し、反応開始点から6時間反応させた。混合溶液のモル比はSiO2:Pluronic
P123:Na2O:HCl:H2O
=1:0.017:0.312:5.88:201.5であり、TiCl4の同モル比は0.45である。尚、H2Oには全ての原料由来の水が含まれている。反応後固体生成物を濾別し、洗浄後、50℃で十分乾燥させる。最終的に600℃の電気炉中で1時間焼成を行うことで有機成分を除去し薄板状Ti含有多孔質シリカ金属複合体粒子を得る。
Table 1 shows Ti mol%, BET specific surface area, total pore volume, micropore volume, and solid acid amount in the thin plate-like Ti-containing porous silica metal composite particles of this example.
(Example 2)
Commercially available JIS No. 3 sodium silicate (SiO 2 : 23.6%, Na 2 O: 7.59%) diluted with water was dissolved in 2N hydrochloric acid, a triblock copolymer Pluronic.
P123 (PE
O 20 PPO 70 PEO 20 ) (average molecular weight 5800) (Aldrich) is added with stirring. Both raw material solutions are adjusted in advance to a predetermined temperature of 25 ° C. and mixed (reaction starting point). After mixing both raw material solutions, titanium chloride is quickly added, and stirring is stopped in 1 minute, and 6 hours from the reaction starting point. Reacted. The molar ratio of the mixed solution is SiO 2 : Pluronic
P123: Na 2 O: HCl: H 2 O
= 1: 0.017: 0.312: 5.88: 201.5, and the same molar ratio of TiCl 4 is 0.45. H 2 O contains water derived from all raw materials. After the reaction, the solid product is filtered off, washed and sufficiently dried at 50 ° C. Finally, the organic component is removed by firing in an electric furnace at 600 ° C. for 1 hour to obtain thin plate-like Ti-containing porous silica metal composite particles.
本実施例の生成物の形態、メソ構造並びに固体酸性質の特徴は、実施例1の薄板状Ti含有多孔質シリカ金属複合体粒子と同様である。ただし、図6に示す通り、細孔径は小さく、反応温度によって本発明の薄板状多孔質シリカ金属複合体粒子の細孔径は制御可能なことがわかる。表1に本実施例の薄板状Ti含有多孔質シリカ金属複合体粒子の細孔特性等を記載する。
(実施例3)
水を加えて希釈した市販のJIS3号珪酸ナトリウム(SiO2:23.6%、Na2O:7.59%)を、2Nの塩酸に溶解したトリブロック共重合体Pluronic
P123 (PE
O20PPO70PEO20) (平均分子量5800)(Aldrich)溶液に攪拌しながら添加
する。両原料溶液は予め所定温度25℃に調整して混合し(反応開始点)、両原料溶液を混合後素早くオキシ塩化ジルコニウム(ZrCl2O・8H2O)を添加してから、1分間で攪拌を停止し、反応開始点から6時間反応させた。混合溶液のモル比はSiO2:Pluronic
P123:Na2O:HCl:H2O=1:0.017:0.312:5.88:2
01.5であり、オキシ塩化ジルコニウムの同モル比は0.02(実施例3−1)、0.09(実施例3−2)及び0.18(実施例3−3)である。尚、H2Oには全ての原料由来の水が含まれている。反応後固体生成物を濾別し、洗浄後、50℃で十分乾燥させる。最終的に600℃の電気炉中で1時間焼成を行うことで有機成分を除去し薄板状Zr含有多孔質シリカ金属複合体粒子を得る。
The characteristics of the product form, mesostructure and solid acid properties of this example are the same as those of the lamellar Ti-containing porous silica metal composite particles of Example 1. However, as shown in FIG. 6, it can be seen that the pore diameter is small and the pore diameter of the thin plate-like porous silica metal composite particles of the present invention can be controlled by the reaction temperature. Table 1 shows the pore characteristics and the like of the thin plate-like Ti-containing porous silica metal composite particles of this example.
(Example 3)
Commercially available JIS No. 3 sodium silicate (SiO 2 : 23.6%, Na 2 O: 7.59%) diluted with water was dissolved in 2N hydrochloric acid, a triblock copolymer Pluronic.
P123 (PE
O 20 PPO 70 PEO 20 ) (average molecular weight 5800) (Aldrich) is added with stirring. Both raw material solutions are preliminarily adjusted to a predetermined temperature of 25 ° C. and mixed (reaction starting point). After mixing both raw material solutions, zirconium oxychloride (ZrCl 2 O · 8H 2 O) is quickly added and stirred for 1 minute. Was stopped, and the reaction was continued for 6 hours from the reaction start point. The molar ratio of the mixed solution is SiO 2 : Pluronic
P123: Na 2 O: HCl: H 2 O = 1: 0.017: 0.312: 5.88: 2
The same molar ratio of zirconium oxychloride is 0.02 (Example 3-1), 0.09 (Example 3-2) and 0.18 (Example 3-3). H 2 O contains water derived from all raw materials. After the reaction, the solid product is filtered off, washed and sufficiently dried at 50 ° C. Finally, the organic component is removed by firing in an electric furnace at 600 ° C. for 1 hour to obtain thin plate-like Zr-containing porous silica metal composite particles.
図1Aおよび図2Aに示した実施例1における形態並びにメソ構造の特徴は、本実施例の薄板状Zr含有多孔質シリカ金属複合体粒子においても同様と認められた。また、図5には本実施例3−2の粉末X線回折パターンを示した。 The form and mesostructure characteristics in Example 1 shown in FIGS. 1A and 2A were also recognized in the thin plate-like Zr-containing porous silica metal composite particles of this example. FIG. 5 shows the powder X-ray diffraction pattern of Example 3-2.
図7は本実施例のアンモニア昇温脱離スペクトルであり、Zr存在量が多くなるほど、脱離量が多いことから固体酸量が大きく、さらにピーク位置がやや高温側にシフトすることから酸強度が強くなることがわかる。 FIG. 7 is an ammonia temperature-programmed desorption spectrum of this example. As the amount of Zr present increases, the amount of desorption increases, so that the amount of solid acid increases, and the peak position shifts slightly to the high temperature side. It turns out that becomes stronger.
表1に本実施例の薄板状Zr含有多孔質シリカ金属複合体粒子中のZrモル%、BET比表面積、全細孔容積、マイクロ孔容積、及び固体酸量を示す。
(実施例4)
水を加えて希釈した市販のJIS3号珪酸ナトリウム(SiO2:23.6%、Na2O:7.59%)を、2Nの塩酸に溶解したトリブロック共重合体Pluronic
P123 (PEO20PPO70PEO20) (平均分子量5800)(Aldrich)溶液に攪拌しながら添加
する。両原料溶液は予め所定温度25℃に調整して混合し(反応開始点)、両原料溶液を混合後素早く硝酸ジルコニル(Zr(NO3)2O・2H2O)を添加してから、1分間で攪拌を停止して、反応開始点から6時間反応させた。混合溶液のモル比はSiO2:Pluronic
P123:Na2O:HCl:H2O=1:0.017:0.312:5.88:2
01.5であり、硝酸ジルコニルの同モル比は0.05(実施例4−1)、0.10(実施例4−2)及び0.16(実施例4−3)である。尚、H2Oには全ての原料由来の水が含まれている。反応後固体生成物を濾別し、洗浄後、50℃で十分乾燥させる。最終的に600℃の電気炉中で1時間焼成を行うことで有機成分を除去し薄板状Zr含有多孔質シリカ粒子を得る。
Table 1 shows Zr mol%, BET specific surface area, total pore volume, micropore volume, and solid acid amount in the thin plate-like Zr-containing porous silica metal composite particles of this example.
Example 4
Commercially available JIS No. 3 sodium silicate (SiO 2 : 23.6%, Na 2 O: 7.59%) diluted with water was dissolved in 2N hydrochloric acid, a triblock copolymer Pluronic.
P123 (PEO 20 PPO 70 PEO 20 ) (average molecular weight 5800) (Aldrich) is added with stirring. Both raw material solutions are adjusted in advance to a predetermined temperature of 25 ° C. and mixed (reaction starting point). After mixing both raw material solutions, zirconyl nitrate (Zr (NO 3 ) 2 O.2H 2 O) is added quickly, and then 1 Stirring was stopped in minutes, and the reaction was allowed to proceed for 6 hours from the reaction start point. The molar ratio of the mixed solution is SiO 2 : Pluronic
P123: Na 2 O: HCl: H 2 O = 1: 0.017: 0.312: 5.88: 2
The same molar ratio of zirconyl nitrate is 0.05 (Example 4-1), 0.10 (Example 4-2) and 0.16 (Example 4-3). H 2 O contains water derived from all raw materials. After the reaction, the solid product is filtered off, washed and sufficiently dried at 50 ° C. Finally, the organic component is removed by firing in an electric furnace at 600 ° C. for 1 hour to obtain thin plate-like Zr-containing porous silica particles.
図1、図2、図5に示した実施例1における形態並びにメソ構造の特徴は、本実施例の薄板状Zr含有多孔質シリカ金属複合体粒子においても同様と認められた。 The characteristics of the form and mesostructure in Example 1 shown in FIGS. 1, 2, and 5 were also recognized in the thin plate-like Zr-containing porous silica metal composite particles of this example.
図8は本実施例のアンモニア昇温脱離スペクトルであり、Zr存在量が多くなるほど、脱離量が多いことから固体酸量が大きいことがわかる。 FIG. 8 is an ammonia temperature-programmed desorption spectrum of this example, and it can be seen that as the amount of Zr present increases, the amount of solid acid increases because the amount of desorption increases.
図9は、本実施例の薄板状Zr含有多孔質シリカ金属複合体粒子の細孔径分布曲線である。 FIG. 9 is a pore size distribution curve of the thin plate-like Zr-containing porous silica metal composite particles of this example.
表1に本実施例の薄板状Zr含有多孔質シリカ金属複合体粒子中のZrモル%、BET比表面積、全細孔容積、マイクロ孔容積、及び固体酸量を示す。
(実施例5)
水を加えて希釈した市販のJIS3号珪酸ナトリウム(SiO2:23.6%、Na2O:7.59%)を、2Nの塩酸に溶解したトリブロック共重合体Pluronic
P123 (PE
O20PPO70PEO20)(平均分子量5800)(Aldrich)溶液に攪拌しながら添加
する。両原料溶液は予め所定温度37℃に調整して混合する(反応開始点)。両原料溶液を混合後素早く直ちにオキシ塩化ジルコニウム(ZrCl2O・8H2O)を添加し、30秒経過した後攪拌を停止し、60〜160℃の一定温度に保持した乾燥機内に反応容器を移し、反応開始点から6時間静置し熟成した。混合溶液のモル比はSiO2:Pluronic
P123:Na2O:HCl:H2O=1:0.017:0.312:5.88:201.
5であり、ZrCl2O・8H2Oの同モル比は0.09である。尚、H2Oには全ての原料由来の水が含まれている。反応後固体生成物を濾別し、洗浄後、65℃で十分乾燥させる。最終的に600℃の電気炉中で1時間焼成を行うことで有機成分を除去し薄板状Zr含有多孔質シリカ金属複合体粒子を得る。
Table 1 shows Zr mol%, BET specific surface area, total pore volume, micropore volume, and solid acid amount in the thin plate-like Zr-containing porous silica metal composite particles of this example.
(Example 5)
Commercially available JIS No. 3 sodium silicate (SiO 2 : 23.6%, Na 2 O: 7.59%) diluted with water was dissolved in 2N hydrochloric acid, a triblock copolymer Pluronic.
P123 (PE
O 20 PPO 70 PEO 20 ) (average molecular weight 5800) (Aldrich) is added with stirring. Both raw material solutions are adjusted in advance to a predetermined temperature of 37 ° C. and mixed (reaction starting point). Zirconium oxychloride (ZrCl 2 O · 8H 2 O) is added immediately after mixing both raw material solutions, and after 30 seconds, stirring is stopped and the reaction vessel is placed in a dryer maintained at a constant temperature of 60 to 160 ° C. The mixture was allowed to stand for 6 hours from the reaction start point and aged. The molar ratio of the mixed solution is SiO 2 : Pluronic
P123: Na 2 O: HCl: H 2 O = 1: 0.017: 0.312: 5.88: 201.
5, and the molar ratio of ZrCl 2 O · 8H 2 O is 0.09. H 2 O contains water derived from all raw materials. After the reaction, the solid product is filtered off, washed and sufficiently dried at 65 ° C. Finally, the organic component is removed by firing in an electric furnace at 600 ° C. for 1 hour to obtain thin plate-like Zr-containing porous silica metal composite particles.
表2に、熟成温度を変化させて得られた薄板状Zr含有多孔質シリカ複合体粒子のBET比表面積、全細孔容積、マイクロ孔容積を示す。熟成温度による細孔パラメータの変化が顕著で、特に温度が高いほど細孔径が大きく、120℃以上ではマイクロ孔容積の減少が著しい。図10は細孔径分布曲線である。また、図1B及び図2Bは、それぞれ本実施例5−4の薄板状Zr含有多孔質シリカ金属複合体粒子の走査電子顕微鏡写真と透過型電子顕微鏡写真である。幅1ミクロン、厚さ0.3〜0.4ミクロンの六角薄板状粒子が比較的良く分散して存在していることがわかる。さらに、図2Bから、細孔径が拡張してもハニカム状の規則構造が保持されていることが明瞭で、図11Aに示すXRD回折パターンに認められる低角の複数のピークに対応している。一方、600℃の加熱処理においては高角のXRD回折パターン(図11B)は非晶質構造の特徴であるブロードピークだけが認められ、金属成分が酸化物として結晶化せず、シリカ骨格中に存在することを指示している。
(実施例6)
水を加えて希釈した市販のJIS3号珪酸ナトリウム(SiO2:23.6%、Na2O:7.59%)を、2Nの塩酸に溶解したトリブロック共重合体Pluronic
P123 (PE
O20PPO70PEO20)(平均分子量5800)(Aldrich)溶液に攪拌しながら添加
する。両原料溶液は予め所定温度37℃に調整して混合する(反応開始点)。両原料溶液を混合後素早く直ちに塩化チタン(TiCl4)を添加し30秒経過した後、攪拌を停止し、60〜150℃の一定温度に保持した乾燥機内に反応容器を移し、反応開始点から6時間静置し熟成した。混合溶液のモル比はSiO2:Pluronic
P123:Na2O:HCl
:H2O=1:0.017:0.312:5.88:201.5であり、TiCl4の同モル比は0.45である。尚、H2Oには全ての原料由来の水が含まれている。反応後固体生成物を濾別し、洗浄後、65℃で十分乾燥させる。最終的に600℃の電気炉中で1時間焼成を行うことで有機成分を除去し薄板状Ti含有多孔質シリカ金属複合体粒子を得る。
Table 2 shows the BET specific surface area, total pore volume, and micropore volume of the thin plate-like Zr-containing porous silica composite particles obtained by changing the aging temperature. The change in pore parameters due to the aging temperature is remarkable, and in particular, the higher the temperature is, the larger the pore diameter is. FIG. 10 is a pore size distribution curve. 1B and 2B are a scanning electron micrograph and a transmission electron micrograph of the thin plate-like Zr-containing porous silica metal composite particles of Example 5-4, respectively. It can be seen that hexagonal thin plate-like particles having a width of 1 micron and a thickness of 0.3 to 0.4 micron are relatively well dispersed. Further, from FIG. 2B, it is clear that the honeycomb-like regular structure is maintained even when the pore diameter is expanded, and corresponds to a plurality of low-angle peaks observed in the XRD diffraction pattern shown in FIG. 11A. On the other hand, in the heat treatment at 600 ° C., the high-angle XRD diffraction pattern (FIG. 11B) has only a broad peak characteristic of the amorphous structure, and the metal component does not crystallize as an oxide and exists in the silica skeleton. Instructed to do.
(Example 6)
Commercially available JIS No. 3 sodium silicate (SiO 2 : 23.6%, Na 2 O: 7.59%) diluted with water was dissolved in 2N hydrochloric acid, a triblock copolymer Pluronic.
P123 (PE
O 20 PPO 70 PEO 20 ) (average molecular weight 5800) (Aldrich) is added with stirring. Both raw material solutions are adjusted in advance to a predetermined temperature of 37 ° C. and mixed (reaction starting point). After mixing both raw material solutions, titanium chloride (TiCl 4 ) was added immediately and after 30 seconds, stirring was stopped, the reaction vessel was transferred to a dryer maintained at a constant temperature of 60 to 150 ° C., and the reaction was started. Aged for 6 hours. The molar ratio of the mixed solution is SiO 2 : Pluronic
P123: Na 2 O: HCl
: H 2 O = 1: 0.017: 0.312: 5.88: 201.5, and the same molar ratio of TiCl 4 is 0.45. H 2 O contains water derived from all raw materials. After the reaction, the solid product is filtered off, washed and sufficiently dried at 65 ° C. Finally, the organic component is removed by firing in an electric furnace at 600 ° C. for 1 hour to obtain thin plate-like Ti-containing porous silica metal composite particles.
表2に、熟成温度を変化させて得られた薄板状Ti含有多孔質シリカ複合体粒子のBET比表面積、全細孔容積、マイクロ孔容積を示す。細孔径分布を図10に示す。なお、SEM像、TEM像並びにXRD回折パターンはそれぞれ図1、図2、図11に相当する特徴を有している。 Table 2 shows the BET specific surface area, total pore volume, and micropore volume of the lamellar Ti-containing porous silica composite particles obtained by changing the aging temperature. The pore size distribution is shown in FIG. Note that the SEM image, the TEM image, and the XRD diffraction pattern have features corresponding to FIGS. 1, 2, and 11, respectively.
従来50℃以上の高温において薄板状シリカ金属複合体粒子を製造することは不可能であったが、実施例5及び実施例6の結果から、本発明の新規製造法によって高温でも細孔の規則配列構造を有する薄板状シリカ金属複合体粒子が得られることが明らかになった(図1B、図2B)。しかも、熟成温度によって細孔径の制御でき、薄板状形態を破壊することなく、図10に示す通り高温ほど細孔径は大きく10nm以上のメソ細孔を賦与することが可能である。さらに、熟成温度を一定として、熟成時間によっても同様にマクロ形態を保持したまま細孔径を制御することも可能である。 Conventionally, it was impossible to produce the thin-plate silica metal composite particles at a high temperature of 50 ° C. or higher. However, from the results of Example 5 and Example 6, the new production method of the present invention allows pore regulation even at high temperatures. It became clear that thin-plate-like silica metal composite particles having an array structure can be obtained (FIGS. 1B and 2B). Moreover, the pore diameter can be controlled by the aging temperature, and the mesopores having a larger pore diameter can be imparted as the temperature increases as shown in FIG. 10 without destroying the thin plate form. Furthermore, it is also possible to control the pore diameter while maintaining the macro form according to the aging time while keeping the aging temperature constant.
なお、製造方法並びに反応温度(熟成温度)による含有金属量の差異は僅かであり、したがって固体酸量への影響もほとんど認められないことから、表2の実施例全てにおいて金属含有量と固体酸量の測定は行っていない。
(実施例7)
実施例5および実施例6に記載の一部の反応生成物を1000℃まで2時間で昇温し、さらに1000℃で1時間保持し加熱生成物を作製した。表3に得られた薄板状金属含有多孔質シリカ金属複合体粒子の構造特性パラメータを示す。1000℃加熱処理生成物のBET比表面積、全細孔容積並びに細孔径は、600℃(表2)の場合と比較すると、いずれも減少し、マイクロ孔の存在は認められなくなる。しかし、薄板状形態は加熱処理温度によって変わらず、1000℃処理生成物は図1と同様なマクロ形態を有している。図12Aは本実施例7−3(表2の実施例5−4に対応)のTEM写真であり、細孔径は減少するものの、図2B同様ハニカム状に規則配列した細孔が薄板状粒子を貫通して存在することが明瞭であり、この規則配列構造は図13Aに示すXRD回折パターンの低角に存在する複数のピークとして認められる。さらに、図13Bの高角側のXRD回折パターン上に認められるZrO2酸化物に帰属されるブロードピークの存在は、低温ではシリカ細孔壁中に4配位で存在したZr元素が、高温での加熱処理によってZrO2に結晶化することを示している。図12Bに示す高倍のTEM写真は、ZrO2粒子が5nm以下の微粒子として高分散状態で存在することを示している。
(比較例1)
水を加えて希釈した市販のJIS3号珪酸ナトリウム(SiO2:23.6%、Na2O:7.59%)を、2Nの塩酸に溶解したトリブロック共重合体Pluronic
P123 (PE
O20PPO70PEO20) (平均分子量5800)(Aldrich)溶液に攪拌しながら添加
する。両原料溶液は予め所定温度に調整して混合し(反応開始点)、金属塩を添加せず、45秒間で攪拌を停止して、反応開始点から6時間反応させた。混合溶液のモル比はSiO2:Pluronic
P123:Na2O:HCl:H2O=1:0.017:0.312:5.
88:201.5であり、反応温度を25℃(比較例1−1)と36℃(比較例1−2)とした。尚、H2Oには全ての原料由来の水が含まれている。反応後固体生成物を濾別し、洗浄後、65℃で十分乾燥させる。最終的に600℃の電気炉中で1時間焼成を行うことで有機成分を除去し薄板状多孔質シリカ粒子を得る。
In addition, since the difference in the amount of contained metal due to the production method and reaction temperature (aging temperature) is slight, and therefore there is almost no influence on the amount of solid acid, the metal content and the solid acid in all the examples in Table 2 are not observed. The quantity is not measured.
(Example 7)
Some reaction products described in Example 5 and Example 6 were heated to 1000 ° C. in 2 hours, and further maintained at 1000 ° C. for 1 hour to produce a heated product. Table 3 shows structural characteristic parameters of the obtained thin plate-like metal-containing porous silica metal composite particles. The BET specific surface area, total pore volume, and pore diameter of the 1000 ° C. heat-treated product are all reduced as compared with the case of 600 ° C. (Table 2), and the presence of micropores is not recognized. However, the thin plate shape does not change depending on the heat treatment temperature, and the 1000 ° C. treated product has the same macro form as in FIG. FIG. 12A is a TEM photograph of Example 7-3 (corresponding to Example 5-4 in Table 2). Although the pore diameter is reduced, the pores regularly arranged in a honeycomb shape are thin plate-like particles as in FIG. 2B. It is clear that it exists through, and this ordered arrangement structure is recognized as a plurality of peaks existing at a low angle of the XRD diffraction pattern shown in FIG. 13A. Furthermore, the existence of a broad peak attributed to the ZrO 2 oxide observed on the XRD diffraction pattern on the high angle side of FIG. Shows crystallization to ZrO 2 . The high-magnification TEM photograph shown in FIG. 12B shows that ZrO 2 particles exist in a highly dispersed state as fine particles of 5 nm or less.
(Comparative Example 1)
Commercially available JIS No. 3 sodium silicate (SiO 2 : 23.6%, Na 2 O: 7.59%) diluted with water was dissolved in 2N hydrochloric acid, a triblock copolymer Pluronic.
P123 (PE
O 20 PPO 70 PEO 20 ) (average molecular weight 5800) (Aldrich) is added with stirring. Both raw material solutions were adjusted in advance to a predetermined temperature and mixed (reaction starting point), the metal salt was not added, stirring was stopped in 45 seconds, and the reaction was performed for 6 hours from the reaction starting point. The molar ratio of the mixed solution is SiO 2 : Pluronic
P123: Na 2 O: HCl: H 2 O = 1: 0.017: 0.312: 5.
88: 201.5, and the reaction temperature was 25 ° C. (Comparative Example 1-1) and 36 ° C. (Comparative Example 1-2). H 2 O contains water derived from all raw materials. After the reaction, the solid product is filtered off, washed and sufficiently dried at 65 ° C. Finally, the organic component is removed by baking in an electric furnace at 600 ° C. for 1 hour to obtain thin plate-like porous silica particles.
図14Aは、本比較例1−1のシリカ多孔質粒子の走査電子顕微鏡写真である。表1には細孔特性を示した。反応温度が25℃と低い場合には、薄板状の幅1ミクロン、厚さ0.6ミクロンの六角薄板状粒子が凝集して得られる。一方、図14Bから明らかなように、36℃では長さ約1ミクロンに伸張したロッド状粒子となることがわかる。 FIG. 14A is a scanning electron micrograph of the porous silica particles of Comparative Example 1-1. Table 1 shows the pore characteristics. When the reaction temperature is as low as 25 ° C., hexagonal thin plate-like particles having a width of 1 μm and a thickness of 0.6 μm are obtained by aggregation. On the other hand, as is apparent from FIG. 14B, it can be seen that at 36 ° C., rod-like particles extending to about 1 micron in length are obtained.
図14並びに図1から、金属塩の添加によって、薄板状粒子の厚さが薄くなり、さらに金属によっては反応温度が高くても薄い粒子が得られることが明らかである。従って、金属塩の添加は薄板状粒子の形成を促進する作用を有していることと考えられる。
(比較例2)
実施例5に記載の一部の反応生成物を600℃で1時間加熱した生成物を、さらに1200℃まで2時間で昇温し、1200℃で1時間保持した。得られた加熱生成物についてはいずれも窒素吸着等温線を正確に測定することはできず、比表面積は5m2/g以下と
推定される。XRD回折パターンにおいて、回折角0.5から5度(CuKα)の低角に回折ピークが存在しないことからも、1200℃では細孔が消失したことが分かる。高角のXRD回折パターンを1000℃と比較すると、非晶質シリカとZrO2に起因するピークはブロードであるが、いずれも強度が大きくなり結晶化が進んでいることが明瞭であった。
From FIG. 14 and FIG. 1, it is clear that the addition of the metal salt reduces the thickness of the lamellar particles, and depending on the metal, thin particles can be obtained even at a high reaction temperature. Therefore, it is considered that the addition of the metal salt has an action of promoting the formation of the thin plate particles.
(Comparative Example 2)
A product obtained by heating a part of the reaction product described in Example 5 at 600 ° C. for 1 hour was further heated to 1200 ° C. in 2 hours and held at 1200 ° C. for 1 hour. None of the obtained heating products can accurately measure the nitrogen adsorption isotherm, and the specific surface area is estimated to be 5 m 2 / g or less. In the XRD diffraction pattern, it can be seen that the pores disappeared at 1200 ° C. because there is no diffraction peak at a low angle of diffraction angle of 0.5 to 5 degrees (CuKα). When the high-angle XRD diffraction pattern was compared with 1000 ° C., the peaks attributed to amorphous silica and ZrO 2 were broad, but it was clear that both of them were strong and the crystallization progressed.
一方、図15に示すSEM像から、本比較例は、1200℃の高温焼成においても薄板状の形態を保持し、厚さ0.5μm未満の無孔性の薄板状シリカ金属複合体粒子が作製できることを示している。 On the other hand, from the SEM image shown in FIG. 15, this comparative example maintains a thin plate-like form even at a high temperature firing of 1200 ° C., and produces non-porous thin plate-like silica metal composite particles having a thickness of less than 0.5 μm. It shows what you can do.
本発明による薄板状多孔質シリカ金属複合体粒子は、メソ孔と連結して共存するマイクロ孔を利用して強吸着作用とメソ孔による粒子内拡散能に優れていることから、環境汚染排出ガス状物質等の浄化プロセスへの応用、あるいはゼオライトやシリカゲルに代わるシリカ系多孔体として新規用途を導くことが期待される。さらに、薄板状形態を利用することによって、樹脂添加剤、インク吸着用フィラー、増粘剤等の用途や、さらには単独乃至他の無機物質および有機化合物と混合することによりフェルト様に加工成型し、各種フィルター素材として広く利用することが可能である。特に、細孔径が広範囲に制御できることから、大きなメソ孔を利用することによって、酵素あるいは有機官能基を有する大きな分子の吸着・分離・吸蔵・固定剤等として利用することができる。さらに、薄板状多孔質シリカ金属複合体粒子は、シリカ骨格中の金属元素が触媒能発現の活性サイトとなり酸化触媒、還元触媒あるいはそれらの触媒担体として、光触媒等を含め種々の用途に使用できる。また、本薄板状多孔質シリカ金属複合体粒子は、1000℃以上の高温焼成を行っても、形状並びにハニカム状の細孔配列構造を保持することから、高耐熱性薄板状多孔質シリカ金属複合体粒子として上記の他種々の用途に利用できる。 The thin plate-like porous silica metal composite particles according to the present invention are excellent in the strong adsorption action and the intra-particle diffusivity by utilizing the micropores that are connected to the mesopores. It is expected to lead to new applications as a silica-based porous material in place of zeolite and silica gel for application to purification processes of particulate substances. Furthermore, by using the thin plate shape, it can be processed and molded like a felt by mixing with resin additives, ink adsorbing fillers, thickeners, etc., or alone or with other inorganic substances and organic compounds. It can be widely used as various filter materials. In particular, since the pore diameter can be controlled over a wide range, by using large mesopores, it can be used as an adsorbing / separating / occluding / fixing agent for large molecules having enzymes or organic functional groups. Furthermore, the thin plate-like porous silica-metal composite particles can be used for various applications including photocatalysts as oxidation catalysts, reduction catalysts, or catalyst carriers thereof as the active sites for the expression of catalytic activity by the metal elements in the silica skeleton. In addition, since the present thin plate-like porous silica metal composite particles retain their shape and honeycomb-like pore arrangement structure even when fired at a high temperature of 1000 ° C. or higher, they are highly heat-resistant thin plate-like porous silica metal composite particles. As body particles, it can be used in various other applications.
Claims (17)
(Si1−nMn)O2
式中、Mは多価金属としてのTi又はZrを表し、
nはゼロを含まない0.1以下の数である、
で表される化学的組成を有し、走査型顕微鏡観察により薄板状粒子の薄板の厚さが0.5μm未満であり、シリケート骨格中のSi原子が多価金属Mで置換されていることを特徴とする薄板状多孔質シリカ金属複合体粒子。 Formula (Si 1-n M n) O 2
In the formula, M represents Ti or Zr as a polyvalent metal,
n is a number of 0.1 or less not including zero,
The thickness of the thin plate of the thin plate-like particles is less than 0.5 μm by scanning microscope observation, and the Si atom in the silicate skeleton is substituted with the polyvalent metal M. A thin plate-like porous silica metal composite particle.
An oxidation catalyst or a carrier thereof comprising the lamellar porous silica metal composite particles according to any one of claims 1 to 5, 9, and 10.
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